Method and system for controlling a vehicle given to a third party

ABSTRACT

A method and system for controlling a vehicle given to a third party. The system includes a system controller; a mode-indicating device coupled to the system controller; and an authenticator coupled to the system controller. Here, the system controller is adapted to communicate a driving restriction to the vehicle upon an activation of the mode-indicating device by an authorized driver and until a deactivation of the mode-indicating device by the authorized driver, the system controller is adapted to restrict the activation and the deactivation of the mode-indicating device unless the authorized driver has been authenticated by the authenticator, and the driving restriction includes a limit selected from the group consisting of a limit in number of starts, a limit in speed, a limit in acceleration, a limit in number of minutes, a limit in distance, a limit in gears, a limit in locations, and combinations thereof.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application claims priority to and the benefit of U.S. ProvisionalApplication No. 60/773,141, filed on Feb. 13, 2006, and U.S. ProvisionalApplication No. 60/789,822, filed on Apr. 5, 2006, the entire contentsof which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to method and system for controlling avehicle given to a third party.

BACKGROUND OF THE INVENTION

According to the National Institute on Alcohol Abuse and Alcoholism No.25 PH 351 July 1994, “Epidemiologic studies reveal the extent ofalcohol's effect on transportation safety in the United States. First,40 percent of all traffic fatalities (the leading cause of accidentaldeath) are alcohol related. Second, although alcohol has not beendirectly implicated in U.S. commercial airline crashes, typicalestimates of alcohol involvement by pilots in fatal general aviationcrashes range from 10 to 30 percent. Third, a recent review of CoastGuard reports suggests possible alcohol involvement in 60 percent ofboating fatalities (including persons who fell overboard). Finally, inpost-accident testing of railroad employees in 1990, 3.2 percent testedpositive for alcohol or other prohibited drugs. The percentage ofalcohol or other drug involvement may be higher when a fatality isinvolved.”

As such, there is a need for a method and system adapted to test and/orprevent an intoxicated individual from operating a vehicle or otherdevice, whether it is a car, boat, plane, bus, heavy equipment, or entrypoint.

Biometric authentication sensors have been used to prevent or limitaccess to secure facilities and as a substitute for alternative forms ofsecurity such as keycards or passwords. Biometric sensors are oftenconsidered superior to other identification systems as they aregenerally more difficult to disable, tamper with, or bypass. However,biometric sensors have still not gained wide acceptance in the field ofautomobiles and other vehicles. This may be because biometric sensorsare expensive, difficult to integrate with existing vehicles, ordifficult to operate.

The operation of a vehicle normally requires only a key. Anti-theftdevices exist which add security based on a pass code. More advancedanti-theft devices exist to disable vehicles if biometricauthentication, such as a fingerprint scan, is unsuccessful. Limitedstandalone breathalyzer devices exist to disable a vehicle if a driver'sblood alcohol level exceeds preset levels.

Vehicle control systems are severely lacking in a variety of aspects.For example, there is not one individual system that ties each of theelements together. For example, to require a breathalyzer test and abiometric identification would presently require two distinct systemsthat are redundant, costly, and not necessarily compatible.

Also, although substance testing, such as alcohol testing, is typicallyassociated with driving under the influence (DUI), it can also beassociated with medicine, workplace safety, probation monitoring, etc.Breath and in-vitro (e.g., blood and saliva) substance measurementmethods are currently used to correlate (determine) a concentration ofthe substance in a person. The breath and in-vitro substance measurementtechniques suffer from three key limitations. That is, they requirehandling of a bodily fluid, which gives rise to biohazard concerns, theyrequire some degree of direct subject supervision from a testadministrator, and they do not measure the concentration of substanceactually in the person in real time.

Therefore, there is a need for a method and system for non-invasiveand/or in-vivo substance testing that can improve biohazard safetyand/or provide unsupervised and/or actual real time testing. Further,there exists a need for a method and system that can be combinable withan authenticator, such as a biometric sensor, to automate the testing,reduce and/or eliminate fraud and/or the need for supervision duringtesting and/or to prevent or limit an intoxicated individual fromoperating a vehicle or other device, whether it is a car, boat, plane,bus, heavy equipment, or entry point. The coupling of the biometricsensor with the substance testing system should be as close as possiblefor concurrent and/or substantially simultaneous authentication andsubstance evaluation.

SUMMARY OF THE INVENTION

An aspect of an embodiment of the present invention is directed to alight source (such as an LED(s)), a mercury xenon arc lamp, a tungstenhalogen lamp, or a diode laser at a specific (single) wavelength fornon-invasive and/or in-vivo testing of a concentration of a substance ina tissue of a person. Another aspect of an embodiment of the presentinvention is directed to two or more specific wavelengths fornon-invasive and/or in-vivo substance analysis. Another aspect of anembodiment of the present invention is directed to a base reading and alater reading for comparison and/or determination of a concentration ofa substance in a tissue of a person. Another aspect of an embodiment ofthe present invention couples a biometric sensor with a substance sensorat close proximate locations for concurrent and/or substantialsimultaneous authentication and substance evaluation. Another aspect ofan embodiment of the present invention provides a method and system forcontrolling a vehicle given to a third party (e.g., a valet).

An embodiment of the present invention is directed to an opticalsubstance detector including a light source (e.g., a halogen lamp) and afiber optic bundle attached to the halogen lamp to illuminate a testsample (e.g., an area of the test sample) with a configured wavelengthfiltering system. The desired wavelength bands are reflected back to adetector. Through an evaluation involving a statistical modelinganalysis, the test sample's blood alcohol concentration (BAC) isdetermined with respect to a legal limit to operate a vehicle and, ifthe BAC is not within the legal limit, the vehicle is disabled.

An embodiment of the present invention provides a system for preventinguse of a vehicle by an operator of the vehicle. The system includes asystem controller; a biometric authenticator coupled to the systemcontroller; and a substance detecting device adapted to provide asubstance level in the operator to the system controller. Here, thesystem controller is adapted to communicate a driving restriction to thevehicle if the substance level in the operator is above a tolerancelevel or if the operator is not authenticated by the authenticator, thesubstance level is determined at an extremity of the operator, theoperator is also authenticated at the extremity, and the extremity isselected from the group consisting of finger, thumb, toe, ear, palm,sole, foot, hand, and head.

In one embodiment, the system controller is further adapted tocommunicate with the vehicle to permit the vehicle to start if theoperator has been authenticated by the authenticator and the substancelevel in the operator is not above the tolerance level.

In one embodiment, the authenticator includes a biometric authenticatorselected from the group consisting of a fingerprint authenticator, aface recognition authenticator, a hand-geometry authenticator, a voiceauthenticator, and combinations thereof.

In one embodiment, the authenticator includes a fingerprint sensor, andwherein the substance level in the operator is determined in-vivo withinthe finger of the operator.

In one embodiment, the substance detecting device is adapted to detectan alcohol level in the operator.

In one embodiment, the substance detecting device includes a broadbanddetector. The substance detecting device may further include a lightsource configured to direct a light beam at a specific wavelength bandtoward the broadband detector, which may be achieved by directing thelight beam at an extremity such that reflected light is received by thedetector. The specific wavelength band may be within a range from about1300 nm to about 2400 nm. The range may be selected from the groupconsisting of a first range from about 1400 nm to about 1500 nm, asecond range from about 1650 nm to about 1750 nm, and a third range fromabout 2200 nm to about 2400 nm. The specific wavelength band may be atabout 1450 nm. The broadband detector may be a single detector. Thesingle detector may be an InGaAs detector.

In one embodiment, the extremity is the finger.

In one embodiment, the substance detecting device includes a broadbanddetector, a first light beam at a first specific wavelength banddirected toward the broadband detector, and a second light beam at asecond specific wavelength band directed toward the broadband detector.The first specific wavelength band may be at a wavelength where ethanolis less absorptive than water and the second specific wavelength band isat a wavelength where ethanol is more absorptive than water. Thebroadband detector may be a single detector. The single detector may bean InGaAs detector. The first specific wavelength band may be within arange from about 1400 nm to about 1500 nm and the second specificwavelength band may be within a range from about 1650 nm to about 1750nm. Alternatively, the first specific wavelength band may within a rangefrom about 1400 nm to about 1500 nm and the second specific wavelengthband may be within a range from about 2200 nm to about 2400 nm.

In one embodiment, the substance detecting device includes a broadbanddetector, a first light beam at a first specific wavelength banddirected toward the broadband detector, a second light beam at a secondspecific wavelength band directed toward the broadband detector, and athird light beam at a third specific wavelength band directed toward thebroadband detector. The broadband detector may be a single detector. Thefirst specific wavelength band may be within a range from about 1400 nmto about 1500 nm, the second specific wavelength band may be within arange from about 1650 nm to about 1750 nm, and the third specificwavelength band may be within a range from about 2200 nm to about 2400nm. The first specific wavelength band may be at about 1450 nm. In oneembodiment, the system for preventing use of the vehicle by the operatorof the vehicle may further include a light source configured to providethe first, second, and third light beams. In one embodiment, the systemfor preventing use of the vehicle by the operator of the vehicle mayfurther include a filtering system disposed between the light source andthe broadband detector and adapted to provide the first, second, andthird light beams at the first, second, and third specific wavelengthbands to the broadband detector.

In one embodiment, the substance detecting device includes a singlebroadband detector selected from the group consisting of a PbS detector,a PbSe detector, an InAs detector, an InGaAs detector, an InSb detector,and a HgCdTe detector and a light source adapted to direct a light beamat a specific wavelength to the single broadband detector. In oneembodiment, the system for preventing use of the vehicle by the operatorof the vehicle may further include a wavelength filtering systemdisposed between the light source and the single broadband detector andadapted to provide the light beam at the specific wavelength band to thesingle broadband detector. The wavelength filtering system may bedisposed closer in distance to the single broadband detector than to thelight source. In one embodiment, the system for preventing use of thevehicle by the operator of the vehicle may further include a platformcoupled to both the light source and the single broadband detector,wherein the platform is configured to contact a surface of the extremityof the operator and has an index of refraction substantially equal tothat of the surface of extremity of the operator.

In one embodiment, the vehicle includes an automobile. The automobilemay be a rental car.

In one embodiment, the vehicle includes a vehicle selected from thegroup consisting of an aircraft, a mass transit vehicle, a watercraft, apiece of industrial equipment, and a piece of heavy machinery andequipment.

In one embodiment, the authenticator includes a fingerprint sensor, andthe substance level in the operator is determined in-vivo at a tissuewithin the finger of the operator.

In one embodiment, the substance detecting device is adapted to detectan alcohol level in the operator.

In one embodiment, the substance detecting device includes a broadbanddetector. Here, the substance detecting device may further include adiode laser configured to direct a light beam at a specific wavelengthtoward the broadband detector. The broadband detector may be a singlephotodiode detector. The single photodiode detector may be an InGaAsphotodiode detector. The extremity may be the finger.

In one embodiment, the system further includes a credential sensorcoupled to the system controller and adapted to sense a verifiablecredential of the operator. Here, the system controller may be adaptedto verify that the operator authenticated by the authenticator matchesthe verifiable credential of the operator. The verifiable credential mayinclude a credential selected from the group consisting of a driver'slicense, an RFID tag, a smartcard, a credit card, a key ring includingan infrared (IR) adapter, an under-skin implant, and combinationsthereof.

In one embodiment, the substance detecting device includes a broadbanddetector, a first diode laser configured to direct a light beam at afirst specific wavelength toward the broadband detector, and a seconddiode laser configured to direct a light beam at a second specificwavelength toward the broadband detector. Here, the first specificwavelength may be at a wavelength where ethanol is less absorptive thanwater and the second specific wavelength is at a wavelength whereethanol is more absorptive than water. The broadband detector may be asingle photodiode detector. The single photodiode detector may be anInGaAs photodiode detector.

In one embodiment, the substance detecting device includes a broadbanddetector, a first diode laser configured to direct a light beam at afirst specific wavelength toward the broadband detector, a second diodelaser configured to direct a light beam at a second specific wavelengthtoward the broadband detector, and a third diode laser configured todirect a light beam at a third specific wavelength toward the broadbanddetector. Here, the broadband detector is a single photodiode detector.

An embodiment of the present invention provides a time clock system. Thesystem includes a system controller; a biometric authenticator coupledto the system controller; and a substance detecting device adapted toprovide a substance level in an operator of the time clock system to thesystem controller. Here, the substance level is determined at anextremity of the operator, the operator is also authenticated at theextremity, and the extremity is selected from the group consisting offinger, thumb, toe, ear, palm, sole, foot, hand, and head.

In one embodiment, the system controller is adapted to create an alertif the substance level in the operator is above a tolerance level or ifthe operator is not authenticated by the authenticator. The time clocksystem may further include a time clock adapted to determine a time whenthe alert is created.

In one embodiment, the system controller is adapted to communicate witha building security device to permit the operator to access the buildingsecurity device if the operator has been authenticated and theconcentration of the substance is not above a tolerance level. Thesystem controller may also be adapted to communicate with the buildingsecurity device to restrict the operator from accessing the buildingsecurity device if the operator has not been authenticated or theconcentration of the substance is above the tolerance level. Thebuilding access device may include a time clock adapted to determine atime when the operator is permitted access to the building securitydevice.

An embodiment of the present invention provides a system for preventinguse of a vehicle by an operator of the vehicle. The system includes asystem controller; a biometric authenticator adapted to detect at leastone biometric parameter at a first dermal location of an operator of avehicle and generate an authentication output indicating that theoperator has been authenticated; and a substance detecting deviceadapted to detect a level of a substance in the operator at a seconddermal location proximate to the first dermal location and generate alevel output. Here, the system controller operates in response to theauthentication output and the level output to selectively restrict useof the vehicle if the operator is not authenticated or the detectionoutput is above a preselected tolerance value.

In one embodiment, the first dermal location of the operator is alocation capable of biometrically authenticating the operator.

In one embodiment, the first dermal location of the operator is locatedat a fingerprint of the operator.

An embodiment of the present invention provides a method for in-vivomeasurement of a concentration of a substance in a tissue of a person.The method includes directing an incident light beam at a specificwavelength from a diode laser into the tissue; measuring a portion ofthe incident light beam at the specific wavelength reflected from thetissue with a broadband detector; determining a light beam absorption atthe specific wavelength of the substance from the measured portion ofthe incident light beam reflected from the tissue; and calculating theconcentration of the substance in the tissue from the determined lightbeam absorption. Here, the tissue may include the person's blood, and/orthe substance may be alcohol.

In one embodiment, the method further includes authenticating the personwhose tissue is being evaluated via a biometric authenticator and asystem controller. Here, the system controller may be adapted tocommunicate with a controlled vehicle to permit the controlled vehicleto operate if the person has been authenticated and the concentration ofthe substance is not above a tolerance level. The system controller maybe adapted to communicate an operating restriction to the controlledvehicle if the person has not been authenticated or the concentration ofthe substance is above the tolerance level. The controlled vehicle mayinclude an automobile. The automobile may be a rental car. Thecontrolled vehicle may include a vehicle selected from the groupconsisting of an aircraft, a mass transit vehicle, a watercraft, a pieceof industrial equipment, and a piece of heavy machinery and equipmentThe system controller may be adapted to communicate with a buildingsecurity device to permit a person to access the building securitydevice if the person has been authenticated and the concentration of thesubstance is not above a tolerance level. The system controller may beadapted to communicate with the building security device to restrict theperson from accessing the building security device if the person has notbeen authenticated or the concentration of the substance is above thetolerance level. The building access device may include a time clockadapted to determine a time when the person is permitted access to thebuilding security device. The biometric authenticator may include anauthenticator selected from the group consisting of an irisauthenticator, a retinal authenticator, a fingerprint authenticator, aface recognition authenticator, a hand-geometry authenticator, a voiceauthenticator, and combinations thereof. The biometric authenticator mayinclude a fingerprint sensor.

In one embodiment, the broadband detector is a single photodiodedetector. The single photodiode detector may be an InGaAs photodiodedetector.

In one embodiment, the concentration of the substance in the tissue iscalculated using only the determined light beam absorption at thespecific wavelength of the substance.

In one embodiment, the specific wavelength is about 1310 nm.

In one embodiment, the concentration of the substance from thedetermined light beam absorption is calculated by using a firstconcentration regime of the substance having a first light beamabsorption characteristic and a second concentration regime of thesubstance having a second light beam absorption characteristic. Here,the concentration of the substance may be proportional to the light beamabsorption at the specific wavelength of the substance in the firstconcentration regime of the substance, and the concentration of thesubstance may not be proportional to the light beam absorption at thespecific wavelength of the substance in the second concentration regimeof the substance. The second light beam absorption characteristic may bedetermined experimentally. The first light beam absorptioncharacteristic may be determined by:I(λ)=I _(o)(λ)e ^(−α(λ)L),wherein λ is the specific wavelength, Io is an incident intensity of theincident light beam, I is a measured transmitted intensity, α is anabsorption co-efficient as a function of the specific wavelength λ, andL is a mass path length of the portion of the incident light beamtransmitted through the tissue.

In one embodiment, the step of directing the incident light beam at thespecific wavelength from the diode laser into the tissue includesdirecting the incident light beam to strike a mirror to double a masspath length of the portion of the incident light beam transmittedthrough the tissue.

In one embodiment, the step of directing the incident light beam at thespecific wavelength from the diode laser into the tissue includesdirecting the incident light beam to a first side of the tissue, and thestep of measuring the portion of the incident light beam transmittedthrough the tissue includes measuring the portion of the incident lightbeam transmitted through the tissue from a second side of the tissue,and wherein the second side is opposite to the first side.

In one embodiment, the step of directing the incident light beam at thespecific wavelength from the diode laser into the tissue includesdirecting the incident light beam from a first side of the tissue towarda second side of the tissue, and the step of measuring the portion ofthe incident light beam transmitted through the tissue includesmeasuring the portion of the incident light beam transmitted through aportion of the tissue and reflected back to the first side of thetissue.

In one embodiment, the diode laser includes a diode selected from thegroup consisting of a double heterostructure laser diode, a quantum welllaser diode, a distributed feedback laser diode, a vertical cavitysurface emitting laser (VCSEL) diode, and a vertical external-cavitysurface-emitting laser (VECSEL) diode.

In one embodiment, the tissue is located within a finger of the person.

In one embodiment, the specific wavelength is an infrared (IR)wavelength.

An embodiment of the present invention provides a method for in-vivomeasurement of a concentration of a substance in a tissue of a person.The method includes directing a first incident light beam at a firstspecific wavelength from a first diode laser into the tissue; measuringa portion of the first incident light beam at the first specificwavelength reflected from the tissue; determining a first light beamabsorption at the first specific wavelength of the substance from themeasured portion of the first incident light beam reflected from thetissue; directing a second incident light beam at a second specificwavelength from a second diode laser into the tissue; measuring aportion of the second incident light beam at the second specificwavelength reflected from the tissue; determining a second light beamabsorption at the second specific wavelength of the substance from themeasured portion of the second incident light beam reflected from thetissue; and calculating the concentration of the substance in the tissuefrom the determined first light beam absorption and the determinedsecond light beam absorption.

In one embodiment, the concentration of the substance in the tissue iscalculated using only the determined first light beam absorption at thefirst specific wavelength of the substance and the determined secondlight beam absorption at the second specific wavelength.

In one embodiment, the method further includes directing a thirdincident light beam at a third specific wavelength from a third diodelaser into the tissue; measuring a portion of the third incident lightbeam reflected from the tissue; and determining a third light beamabsorption at the third specific wavelength of the substance from themeasured portion of the second incident light beam reflected from thetissue. Here, the step of calculating the concentration of the substancein the tissue also includes calculating the concentration of thesubstance in the tissue from the determined third light beam absorption.

In one embodiment, the concentration of the substance in the tissue iscalculated using only the determined first light beam absorption at thefirst specific wavelength of the substance, the determined second lightbeam absorption at the second specific wavelength, and the determinedthird light beam absorption at the third specific wavelength.

In one embodiment, the first specific wavelength is at a wavelengthwhere ethanol is less absorptive than water and the second specificwavelength is at a wavelength where ethanol is more absorptive thanwater.

In one embodiment, the portion of the second incident light beam at thesecond specific wavelength reflected from the tissue is measured afterthe portion of the first incident light beam at the first specificwavelength reflected from the tissue had been measured.

In one embodiment, the portion of the first incident light beam at thefirst specific wavelength reflected from the tissue and the portion ofthe second incident light beam at the second specific wavelengthreflected from the tissue are measured with a same broadband detector.Here, the same broadband detector may be a single photodiode detector.The single photodiode detector may be an InGaAs photodiode detector.

An embodiment of the present invention provides a method for in-vivomeasurement of a concentration of a substance in a tissue of a person.The method includes directing a first incident light beam at a specificwavelength from a diode laser into the tissue; measuring a portion ofthe first incident light beam at the specific wavelength reflected fromthe tissue; determining a first light beam absorption at the specificwavelength of the substance from the measured portion of the incidentlight beam reflected from the tissue; directing a second incident lightbeam at the specific wavelength from the diode laser into the tissueafter a time interval; measuring a portion of the second incident lightbeam at the specific wavelength reflected from the tissue; determining asecond light beam absorption at the specific wavelength of the substancefrom the measured portion of the second incident light beam reflectedfrom the tissue; and determining a characteristic of change in thetissue from the determined first light beam absorption at the specificwavelength and the determined second light beam absorption at thespecific wavelength.

In one embodiment, the method further includes calculating theconcentration of the substance in the tissue after the time intervalfrom the determined characteristic of change in the tissue. Here, theconcentration of the substance from the determined light beam absorptionmay be calculated by using a first concentration regime of the substancehaving a first light beam absorption characteristic and a secondconcentration regime of the substance having a second light beamabsorption characteristic. The concentration of the substance may beproportional to the light beam absorption at the specific wavelength ofthe substance in the first concentration regime of the substance, andthe concentration of the substance may not be proportional to the lightbeam absorption at the specific wavelength of the substance in thesecond concentration regime of the substance. The second light beamabsorption characteristic may be determined experimentally.

In one embodiment, the specific wavelength is at a wavelength whereethanol is less absorptive than water.

In one embodiment, the specific wavelength is at a wavelength whereethanol is more absorptive than water.

In one embodiment, the tissue includes the person's blood, and/or thesubstance is alcohol.

In one embodiment, the tissue is located within a finger of the person.

In one embodiment, the diode laser includes a diode selected from thegroup consisting of a double heterostructure laser diode, a quantum welllaser diode, a distributed feedback laser diode, a vertical cavitysurface emitting laser (VCSEL) diode, and a vertical external-cavitysurface-emitting laser (VECSEL) diode.

In one embodiment, the portion of the first incident light beam at thespecific wavelength reflected from the tissue and the portion of thesecond incident light beam at the specific wavelength reflected from thetissue are measured with a broadband detector. Here, the broadbanddetector may be a single photodiode detector. The single photodiodedetector may be an InGaAs photodiode detector.

In one embodiment, the tissue is located within a finger of the person.

An embodiment of the present invention provides a method for in-vivomeasurement of a concentration of a substance in a tissue of a person.The method includes directing a first incident light beam at a firstspecific wavelength from a first diode laser into the tissue; measuringa portion of the first incident light beam at the first specificwavelength reflected from the tissue; determining a first light beamabsorption at the first specific wavelength of the substance from themeasured portion of the first incident light beam reflected from thetissue; directing a second incident light beam at a second specificwavelength from a second diode laser into the tissue; measuring aportion of the second incident light beam at the second specificwavelength reflected from the tissue; determining a second light beamabsorption at the second specific wavelength of the substance from themeasured portion of the first incident light beam reflected from thetissue; directing a third incident light beam at the first specificwavelength from the first diode laser into the tissue after a first timeinterval from the directing of the first incident light beam; measuringa portion of the third incident light beam at the first specificwavelength reflected from the tissue; determining a third light beamabsorption at the first specific wavelength of the substance from themeasured portion of the third incident light beam reflected from thetissue; directing a fourth incident light beam at the second specificwavelength from the second diode laser into the tissue after a secondtime interval from the directing of the second incident light beam;measuring a portion of the fourth incident light beam at the secondspecific wavelength reflected from the tissue; determining a fourthlight beam absorption at the second specific wavelength of the substancefrom the measured portion of the fourth incident light beam reflectedfrom the tissue; determining a first characteristic of change in thetissue from the determined first light beam absorption at the firstspecific wavelength and the determined third light beam absorption atthe first specific wavelength; and determining a second characteristicof change in the tissue from the determined second light beam absorptionat the second specific wavelength and the determined fourth light beamabsorption at the second specific wavelength.

In one embodiment, the method further includes calculating theconcentration of the substance in the tissue after the first and secondtime intervals from the first determined characteristic of change in thetissue and the second characteristic of change in the tissue.

In one embodiment, the first time interval is substantially equal to thesecond time interval.

In one embodiment, the method further includes directing a fifthincident light beam at a third specific wavelength from a third diodelaser into the tissue; measuring a portion of the fifth incident lightbeam at the fifth specific wavelength reflected from the tissue;determining a fifth light beam absorption at the third specificwavelength of the substance from the measured portion of the fifthincident light beam reflected from the tissue; directing a sixthincident light beam at the third specific wavelength from the thirddiode laser into the tissue after a third time interval from thedirecting of the fifth incident light beam; measuring a portion of thesixth incident light beam at the sixth specific wavelength reflectedfrom the tissue; determining a sixth light beam absorption at the thirdspecific wavelength of the substance from the measured portion of thesixth incident light beam reflected from the tissue; and determining athird characteristic of change in the tissue from the determined fifthlight beam absorption at the third specific wavelength and thedetermined sixth light beam absorption at the third specific wavelength.Here, the method may further include calculating the concentration ofthe substance in the tissue after the first, second, and third timeintervals from the first determined characteristic of change in thetissue, the second characteristic of change in the tissue, and the thirdcharacteristic of change in the tissue.

An embodiment of the present invention provides a system for controllinga vehicle given to a third party. The system includes a systemcontroller; a mode-indicating device coupled to the system controller;and an authenticator coupled to the system controller. Here, the systemcontroller is adapted to communicate a driving restriction to thevehicle upon an activation of the mode-indicating device by anauthorized driver and until a deactivation of the mode-indicating deviceby the authorized driver, the system controller is adapted to restrictthe activation and the deactivation of the mode-indicating device unlessthe authorized driver has been authenticated by the authenticator, andthe driving restriction includes a limit selected from the groupconsisting of a limit in number of starts, a limit in speed, a limit inacceleration, a limit in number of minutes, a limit in distance, a limitin gears, a limit in locations, and combinations thereof.

In one embodiment, the system further includes a substance detectingdevice coupled to the system controller and adapted to provide asubstance level in the third party to the system controller. Here, thesystem controller may be further adapted to communicate with the vehicleto permit the vehicle to start if the substance level in the third partyis not above a tolerance level. The system controller may be furtheradapted to communicate another driving restriction to the vehicle if thesubstance level in the third party is above the tolerance level. Thedriving restriction may include a command adapted to be sent via avehicle bus of the vehicle to limit a maximum speed of the vehicle, andthe another driving restriction may include a command adapted to be sentvia the vehicle bus of the vehicle to block the vehicle from starting.

In one embodiment, the substance detecting device includes a broadbanddetector. Here, the substance detecting device may further include adiode laser configured to direct a light beam at a specific wavelengthtoward the broadband detector. The broadband detector may be a singlephotodiode detector. The single photodiode detector may be an InGaAsphotodiode detector. The extremity may be the finger.

In one embodiment, the substance detecting device includes a broadbanddetector, a first diode laser configured to direct a light beam at afirst specific wavelength toward the broadband detector, and a seconddiode laser configured to direct a light beam at a second specificwavelength toward the broadband detector. Here, the first specificwavelength may be at a wavelength where ethanol is less absorptive thanwater and the second specific wavelength is at a wavelength whereethanol is more absorptive than water. The broadband detector may be asingle photodiode detector. The single photodiode detector may an InGaAsphotodiode detector.

In one embodiment, the substance detecting device includes a broadbanddetector, a first diode laser configured to direct a light beam at afirst specific wavelength toward the broadband detector, a second diodelaser configured to direct a light beam at a second specific wavelengthtoward the broadband detector, and a third diode laser configured todirect a light beam at a third specific wavelength toward the broadbanddetector. Here, the broadband detector is a single photodiode detector.

In one embodiment, the driving restriction further includes anotherlimit selected from the group consisting of a limit in activatableaccessories, a limit in openable compartments, and combinations thereof.Here, the control panel may be further adapted to send a message to acell phone if the limit has been exceeded to notify a designatedindividual remotely, and/or the control panel may be further adapted tocreate an alert if the limit has been exceeded to notify the authorizeddriver when the authorized driver retakes control of the vehicle.

In one embodiment, the third party is a valet.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, together with the specification, illustrateexemplary embodiments of the present invention, and, together with thedescription, serve to explain the principles of the present invention.

The patent or application file contains at least one drawing executed incolor. Copies of this patent or patent application publication withcolor drawing(s) will be provided by the Office upon request and paymentof the necessary fee.

FIG. 1 shows a block diagram of a driver's card identification systemand/or a system of preventing use (or unauthorized use) of a vehicle byan operator (or driver) of the vehicle pursuant to aspects of anembodiment of the present invention.

FIG. 2 shows a flowchart of process blocks associated with a driver'scard identification system and/or a system of preventing use (orunauthorized use) of a vehicle by an operator (or driver) of the vehiclepursuant to aspects of an embodiment of the present invention.

FIG. 3 shows a visor mounted biometric device pursuant to aspects of anembodiment of the present invention.

FIG. 4 shows a block diagram of an enhanced biometric and substancedetection system and device pursuant to aspects of an embodiment of thepresent invention.

FIG. 4A shows a block diagram of a vehicle including the enhancedbiometric and substance detection system and device of FIG. 4 pursuantto aspects of an embodiment of the present invention.

FIG. 4B shows a block diagram of a time clock system including theenhanced biometric and substance detection system and device of FIG. 4pursuant to aspects of an embodiment of the present invention.

FIG. 5 shows a block diagram of an enhanced biometric and substancedetection system and device pursuant to aspects of another embodiment ofthe present invention.

FIG. 6 shows a spectrum of 100% ethanol at specific wavelengths rangingfrom 800 nm to 2400 nm collected using a research grade NIR spectrometerpursuant to aspects of an embodiment of the present invention.

FIG. 7 shows spectra of 0.10%, 0.08%, 0.06%, and 0.04% ethanol in waterat specific wavelengths ranging from 1400 nm to 1500 nm collected usinga research grade NIR spectrometer pursuant to aspects of an embodimentof the present invention.

FIG. 8 shows spectra of 0.10%, 0.08%, 0.06%, and 0.04% ethanol in waterat specific wavelengths ranging from 1650 nm to 1750 nm collected usinga research grade NIR spectrometer pursuant to aspects of an embodimentof the present invention.

FIG. 9 shows spectra of 0.10%, 0.08%, 0.06%, and 0.04% ethanol in waterat specific wavelengths ranging from 2200 nm to 2400 nm collected usinga research grade NIR spectrometer pursuant to aspects of an embodimentof the present invention.

FIG. 10A shows an optical substance detector configuration according toan embodiment of the present invention.

FIG. 10B shows an optical substance detector configuration according toanother embodiment of the present invention.

FIG. 11 shows ethanol and water optical absorption from 800 to 2400 nmpursuant to aspects of an embodiment of the present invention.

FIG. 12 shows a block diagram of a variety of technologies that can beused pursuant to aspects of an embodiment of the present invention.

FIG. 13 shows a light source, a collimating lens, a finger, a reimaginglens, and a fiber pursuant to aspects of an embodiment of the presentinvention.

FIG. 14 shows a schematic of a finger sensor with integral fingerprintscreen pursuant to aspects of an embodiment of the present invention.

FIG. 15 is a schematic of a photodiode with a transimpedance amplifierand thermal control as envisioned pursuant to aspects of an embodimentof the present invention.

FIG. 16 shows a SHS schematic in which a fiber is used to couple the SHSto the “finger slot” via a fiber optic pursuant to aspects of anembodiment of the present invention.

FIG. 17 shows the use of a filter, tunable or static, to sample lightpursuant to aspects of an embodiment of the present invention.

FIG. 18 shows a filter slider that can be used to change the filter inthe light path sampling at different wavelengths pursuant to aspects ofan embodiment of the present invention.

FIG. 19 shows a spectrometer pursuant to aspects of an embodiment of thepresent invention.

FIGS. 20 and 21 show portions of spectra from 1100 nm to 1700 nmpursuant to aspects of an embodiment of the present invention.

FIG. 22 shows a full spectrum, laser illumination pursuant to aspects ofan embodiment of the present invention.

FIG. 23 shows NIR spectrometer data showing a statistically invalid butintriguing measurement of ethanol concentration versus observedintensity at about 1310 nm pursuant to aspects of an embodiment of thepresent invention.

FIGS. 24A, 24B, and 24C show sample interrogation methods using anarrowband illuminate and photodiode detector pursuant to aspects of anembodiment of the present invention.

FIG. 25 shows detailed operating principles of a monochrometer pursuantto aspects of an embodiment of the present invention.

FIG. 26 shows an ethanol sensor apparatus pursuant to aspects of anembodiment of the present invention.

FIG. 27 shows a transmission intensity at about 1310 nm for samplespursuant to aspects of an embodiment of the present invention.

FIGS. 28 and 29 show results for a 0-0.1% region that did not correspondto Beer's law pursuant to aspects of an embodiment of the presentinvention.

FIG. 30 shows a schematic of a butterfly packaged diode laser withintegral fiber optic pigtail pursuant to aspects of an embodiment of thepresent invention.

FIG. 31 shows two diode lasers with pigtails, each at a distinctwavelength pursuant to aspects of an embodiment of the presentinvention.

FIG. 32 shows a block diagram of a system for controlling a vehiclegiven to a third party, for in-vivo measurement of a concentration of asubstance in a tissue of a person, and/or for preventing use of avehicle by an operator of the vehicle pursuant to aspects of anembodiment of the present invention.

FIG. 33 shows a flowchart of process blocks of system logics forcontrolling a vehicle given to a third party, for in-vivo measurement ofa concentration of a substance in a tissue of a person, and/or forpreventing use of a vehicle by an operator of the vehicle pursuant toaspects of an embodiment of the present invention.

FIG. 34 shows a block diagram of another system for controlling avehicle given to a third party, for in-vivo measurement of aconcentration of a substance in a tissue of a person, and/or forpreventing use of a vehicle by an operator of the vehicle pursuant toaspects of an embodiment of the present invention.

FIGS. 35, 36, 37, and 38 show flowcharts of process blocks of systemlogics for controlling a vehicle given to a third party, for in-vivomeasurement of a concentration of a substance in a tissue of a person,and/or for preventing use of a vehicle by an operator of the vehiclepursuant to aspects of an embodiment of the present invention.

DETAILED DESCRIPTION

In the following detailed description, only certain exemplaryembodiments of the present invention are shown and described, by way ofillustration. As those skilled in the art would recognize, the describedexemplary embodiments may be modified in various ways, all withoutdeparting from the spirit or scope of the present invention.Accordingly, the drawings and description are to be regarded asillustrative in nature, and not restrictive.

As envisioned in an embodiment of the present invention, a driver's cardidentification system is provided. The system allows for, among otherthings, using personal biometrics in combination with verifiablecredentials to restrict and enforce operations of a vehicle. The systemallows restriction to authorized drivers, provides theft protection,assures compliance with driving and/or licensing laws, offerscustomizable control for use by parents or when a vehicle is given to athird party such as a valet, service facility, designated driver,friend, or employee. The system further provides secure, encrypted,verifiable statistical information about a person's driving habits andwho was driving at a particular time. The system may further restrictthe driving of vehicles while under the influence of alcohol or drugs.

One embodiment of the present invention envisions a system that blocksor prevents unauthorized use of a vehicle by using biometrics coupledwith verifiable credentials. This may be accomplished by requiring abiometric verification, such as an iris scan, retinal scan, fingerprintscan, face recognition scan, hand-geometry scan, or voice authenticationin combination with a verifiable credential. A verifiable credential maybe a driver's license with barcode, magnetic stripe, an RFID, asmartcard, a credit card, a key ring including an infrared adapter, anunder-skin implant, or other credential issued by a trusted source. Sucha system could further include adjusting the requirements to start ordrive the vehicle based on the time of day, day of week, number of hoursdriven in a particular time period, driving conditions, location, numberof passengers or their status, government-issued alert status, orplanned route or destination. Such a system may be implemented in avariety of ways. One implementation is through the use of a software andhardware-based tamper-proof control module (or system controller) thataccepts as inputs a biometric authenticator, and a credential-reader.The control module may include or be connected to a database either inthe vehicle or through a wireless connection. The control module canverify that the biometric authentication matches the verifiablecredentials and that the credentials and/or authentication is valid.Based on the results of the verification, the control module maycommunicate with the vehicle computer to permit the vehicle to start orto communicate driving restrictions including those received from thedatabase or wireless connection. The control module may also report anerror or request additional credentials based on the verification,information from the database, or information from the wirelessconnection.

Another embodiment of the present invention envisions a system thatblocks or prevents unauthorized use of a vehicle by using biometricsand/or verifiable credentials coupled with a detection system foralcohol or drugs. Such a system could include requiring a particulardriver or class of drivers to pass a breathalyzer test based on theirbiometric scan and/or use information obtained from the biometricidentification to restrict the use of the vehicle. For example, retinalscanners may identify that a person is under the influence of alcohol ordrugs because the scanned retinal pattern or blood vessel pattern isdifferent for a person under the influence of alcohol and certain drugsas compared to that same person when not under the influence. Further, apupil dilation test may be performed to determine intoxication bymeasuring the speed and extent that the pupil dilates when a beam oflight is flashed at the eye. This change in retinal pattern or pupildilation may be quantifiable or measured as a percent of deviation fromthe expected pattern. If the deviation exceeds a tolerance, then thevehicle may be restricted or may require an alternate form ofverification such as a call to an operator, visit from a police officer,or an alternate proof of sobriety such as a breathalyzer. For example,if a driver who is under the influence of alcohol attempts to verify hisidentity using a retinal scan, a flag in the system could be activatedrequiring him to prove that he is not drunk (such as by notifying apolice officer or family member via wireless communications) ordisabling the vehicle or limiting his speed or route. Such a coupling ofbiometrics with substance detection is beneficial since it allowsdifferent detection thresholds and responses to be set for differentindividuals. It also reduces the likelihood that a friend or passengercould fool a standard ignition lockout breathalyzer device by blowinginto it then letting the intoxicated driver drive. Tolerances could becontrolled from state-to-state or customized to a particular driver bystoring the tolerance level in their credentials. Customization oftolerance levels could allow particular drivers to be authorized todrive if their scan differentiation exceeds certain percentages, such asan elderly person whose eyes may be changing. If an alternate proof isprovided, such as an override code from a police officer, anyinformation about that code would be stored in a log, such as theoverriding officer's badge number.

Another embodiment of the present invention envisions a hand-heldbiometric identification device that may also function as a substancedetector and may also function as a credentials verifier. A hand-heldbiometrics device may include a portable retinal scanner, fingerprintscanner, voice analyzer, iris scanner, RFID reader, face recognitionscanner, or hand-geometry scanner. Such a device may be used by a policeofficer during a traffic stop or wherever highly reliable identificationis desired. The device may include a power supply or battery, abiometric authenticator, a state detector, or a credentialsauthenticator. The device may further include a database or wirelessaccess to a database. The hand-held device may further communicate witha vehicle control module to download biometric information, stateinformation, credentials information, or logs. In an exemplaryembodiment, the hand-held biometric identification device would includea biometric authenticator, in one representative embodiment, a retinalscanner, coupled to a credentials authenticator, in one representativeembodiment, a barcode reader. A government authority, such as a policeofficer, could swipe a person's driver's license and/or insurance card,and perform a retinal scan. The device could then cross-check thelicense, insurance card, and retinal scan to authenticate the identityof the individual. The system may further verify the credentials againsta database to determine that they are currently valid and may interfacewith a computer, such as one in a police car, to determine if there is areason to further detain the individual.

Another embodiment of the present invention envisions a system thatallows parental control of a vehicle through the use of biometricidentification. For instance, a parent may use such a system to assurethat only their child may drive the car and may not lend the car to athird party. Similarly, a parent using such a system may view logs ofdriving statistics such as speed, route, and number of stops. Bycoupling such a system with biometrics, a parent can be assured that theperson driving the vehicle is their child. Further, through the use ofbiometrics coupled to a GPS, a parent could allow their child to driveonly on specific routes, such as to and from school. The system may alsobe optionally reset or driving privileges increased remotely by the useof a pin number, password, or remote authorization. The parental controlsystem may allow multiple ‘home locations’ to be programmed, so that thesystem can track how far the vehicle is from each location. The vehiclemay also be ‘recalled’ home by sending an SMS message or communicationto the vehicle. If a vehicle is recalled, it may restrict the driverfrom deviating from a course home. In the event of a deviation, variousenforcement measures may be taken such as limiting the speed, opening atelephone connection to a phone number, or requiring a reply message tobe sent explaining why the deviation occurred. The parental controlsystem may also be coupled with the state detector to prevent a childfrom operating the vehicle while intoxicated or tired. The system mayfurther provide logs of route, speed, stops, braking habits, and numberof passengers. Driving times may further be restricted during specifiedhours to prevent the driver from operating the vehicle. For parentalcontrols, this may prevent a child from operating the vehicle duringschool hours once they have parked the vehicle. A principal or otherindividual may be preauthorized to allow exceptions to the policy.Preauthorization may occur by that individual's credentials beingentered into the system by the parent.

The system may optionally be connected to a computer or the informationdownloaded wirelessly to allow logs to be analyzed and settings to becustomized. A computer software program may be operable to connect tothe system, authenticate, and download the information. The informationmay be analyzed, published to a web page, or used to provide reports ofthird party driving habits, such as children or employees.

Another embodiment of the present invention envisions a system torestrict driving privileges of particular individuals by a government,police, or law enforcement agency. For example, an individual may onlybe allowed to drive to and from work although the vehicle may be used byother people without such restrictions. Therefore, such a system coulduse biometric verification to enforce particular driving restrictionswith respect to particular drivers.

Another embodiment of the present invention envisions a system thatallows for control of a vehicle given to a third party. A third partymay include a valet, service facility, designated driver, friend, oremployee. The vehicle may be configured to operate in a restrictedcapacity, such as by limiting its speed, acceleration, number of minutesor miles it can travel, gears that it can shift, locations that it cango, accessories that can be activated, or compartments that may beopened. A time-delayed valet button or system may be activated to engagethe restrictions until an authorized driver retakes control of thevehicle or a proper non-valet key is used. A valet may not be requiredto perform a biometric identification, but access to the vehicle wouldbe restricted. A valet option may also include a limited number ofadditional starts, so that the valet has the ability to move the car ifneeded. If the valet attempts to exceed the number of starts or otherrestrictions the vehicle can create an alert and optionally notify adesignated individual remotely, such as by sending an SMS message to acell phone. When such a system is engaged a sound may be emitted or avisual alert provided. The system may also be optionally reset by theuse of a pin number or password. This aspect may be coupled withbiometric identification and/or credential verification to assure easeof operability between drivers.

The system may also be coupled with a state detector such as abreathalyzer, a noninvasive finger scan, a heart rate monitor, brainactivity monitor, or other device for detecting conditions of a driverto restrict driving based on those conditions—for example, to detect theonset of a heart attack or a tired driver or to prevent road rage.

Another embodiment of the present invention envisions a system andmethod adapted to enforce driving restrictions based on biometricverification or verifiable credentials. Vehicles may be equipped todrive on certain designated streets, lanes, or park in particularparking lots based on the driver's identity. Speeds may be limitedthrough the use of a governor or other speed control device based on thebiometric verification or verifiable credentials. Drivers with baddriving histories may be required to limit their speed or routes basedon such biometric identification. Similarly, if the governmentdetermines it is necessary, the driver's credentials may be revoked, orrestrictions may be placed on them which the vehicle would enforce orkeep and/or transmit a log if violated.

Another embodiment of the present invention envisions a master-overridefeature for use by authorized individuals such as police, tow-trucks,and emergency responders. When a vehicle's biometric override featurehas been enabled it may flash lights, emit sounds, or communicatewirelessly with a database or alert system.

Another embodiment of the present invention envisions a visor-mountedbiometrics device. Such a device may be an iris scanner, retinalscanner, or microphone and/or camera. The visor is a particularly goodlocation for such a device since it is generally a fixed distance fromthe driver, may include a mirror or light, may include a swivel oradjustment for height or distance from the driver, and may be easilystowed for cosmetic or antitheft purposes. The biometrics device mayalso continue to operate while the vehicle is in use or when the driverdoor is opened or when a sensor detects a new driver has entered thevehicle. Such a visor mounted biometrics device could also preventcarjacking by assuring that the driver is verified. The visor-mountedbiometrics device may include an entire biometrics system or just oneelement, such as a camera. The logic and circuitry driving thebiometrics device need not be located in the visor. The visor may alsoinclude a series of LEDs to indicate status or success of the biometricssystem or overall system. The visor may also include an LCD display toassist with alignment of the biometrics device in the case of a retinal,iris, or pupil scanner. An LCD in the visor may also display statusinformation about the current driver or the system, which isparticularly beneficial for retrofitting existing vehicles wheredashboard space may be limited. A microphone may also be included in thevisor to perform authentication or for voice-activated control of thesystem.

Another embodiment of the present invention envisions a biometricsauthentication system coupled to an alternate driving device such as ajoystick, eye-tracker, or voice-controlled steering or driving controlsystem. Such a system could include a fingerprint scanner positioned ona joystick, or a retinal scanner that also functions to track eyemovement to control aspects of the driving in addition to providingdriver authentication. A voice-activated biometric identifier may alsobe used for voice-activation of vehicle features such as the radio.

Another embodiment of the present invention envisions a system andmethod adapted to allow the biometric verification or credentialinformation to be wirelessly transmitted to a law enforcement officerduring a chase or when a vehicle is pulled over. Such transmission maybe encrypted by the system and unencrypted by a handheld system or asystem located in the officer's vehicle. The officer may download anylogs from the system wirelessly or view any logs, including the recentroute, speed, or drivers of the vehicle by performing a biometric scancross-checked to their credentials inside the vehicle. The informationmay also be relayed to a central location for further analysis.

Another embodiment of the present invention envisions a system andmethod adapted to allow the biometric verification and credentialinformation to be easily communicated between drivers in the event of avehicle collision. Such communication helps prevent individuals fromproviding false information and provides speed and accuracy of theinformation. The information may be communicated wirelessly or a paperreport may be printed from an in-vehicle printer attached to the system.The information may also be wirelessly transmitted to insurancecompanies or the DMV for a report to be generated.

Another embodiment of the present invention envisions a system andmethod adapted to allow the biometric verification and credentialinformation to be received and stored by a vehicle involved in ahit-and-run accident. Further, such information may be encrypted toprotect privacy and may be brought to a law enforcement agency such asthe DMV or a police station where it can be decrypted. Such a system mayprovide a virtual snapshot of an accident or crime scene, furthering theability of parties and witnesses to be located. The police can alsobacktrack or pull up what routes had previously been driven. Routes maybe stored in an encrypted manner or a checksum may be calculated toconfirm authenticity.

Another embodiment of the present invention envisions a system andmethod adapted to keep a log of the previous drivers of the vehicle. Theinformation may be stored in the system, transmitted wirelessly atparticular intervals, transmitted each time the car is started or thefoot is depressed on the brake, or transmitted at fixed intervals suchas during vehicle renewal.

As envisioned, another embodiment of the present invention furtherincludes charging different individuals different fees based on wherethey are traveling or for what purpose. A pay-per-use refillablecredential may be used to authorize particular individuals to drive tocertain locations at a low cost and to drive to other locations at ahigher cost. For example, driving to work may be charged at a low cost,but driving to a bar at a higher cost. Such costs may be paid atstandalone kiosks or directly billed to a driver's account.

Another embodiment of the present invention envisions a system andmethod adapted to allow the biometric verification or credentialinformation to be transmitted to a parking lot attendant or automatedsystem to provide desired services, such as premium parking spots toparticular customers.

Another embodiment of the present invention envisions a system andmethod adapted to require biometric identification and/or credentialinformation for all individuals entering a vehicle. Such information canbe used to encourage carpooling by restricting access to particularroads based on the individuals in the vehicles, prevent terrorism, orcharge or debit each passenger based on their travel.

Another embodiment of the present invention envisions a wireless vehiclemonitoring system. The monitoring system may include a satelliteconnection, either bidirectional or unidirectional. The wirelessconnection could provide periodic updates of license and insuranceinformation. Further, the system may be configured to power-up orreceive the wireless communications at specific days/times or may beconfigured for constant monitoring. The system may also communicatethrough a cell-phone including via blue-tooth. Providing wirelessupdates may allow the system to work without the need to swipe a validdriver's license or insurance card, as such information would already bestored in the system and matched to a driver's biometric information.Further, the system may be capable of receiving targeted communicationsincluding SMS messages. The communications could be interpreted by thesystem and, upon an initial verification of authenticity or keyexchange, operations contained in the messages could be performed, suchas throttling the speed of the vehicle, shutting down the vehicle,sounding the horn or lights, or updating the system to reflect a changein the verified credentials such as a suspended driver's license.

Another embodiment of the present invention envisions a system andmethod for linking insurance rates and driving taxes to the amount ortype of driving of a driver of a vehicle. Different plans may bepurchased, including an unlimited use plan, a limited mileage plan, asingle-driver plan, and plans that include certain number of over-milesat different prices. Insurance rates may be set based upon theinformation logged in the system. To accomplish this end, the logs maybe transmitted to the insurance company or a summary report may begenerated and sent. Information contained in the insurance ID card mayalso be used to enforce driving restrictions. For example, if the driverexceeds the number of miles on his plan he may be restricted fromcertain routes. Similarly, top-up cards may be purchased or a charge tothe driver's account may be authorized. Drivers with low mileage, lowaverage speed, safe routes, low-traffic routes, or who average a highnumber of passengers may be rewarded by offering a credit, discount, orpoints redeemable for a gift.

Another embodiment of the present invention envisions an easy-to-usevoice-responsive system. The system can provide audible prompts andincludes voice recognition to accept commands. When a driver enters thevehicle the system can greet the driver, prompt the driver to providetheir credentials and biometric information. A cross-check can beperformed and a database queried. If the verification is successful, thedriver may be further greeted, presets may be set on the radio or otherin-vehicle devices, and the vehicle enabled. If the verification failsthe driver may be given additional attempts before being prompted toleave the vehicle. If the driver does not leave the vehicle an alarm maysound or a designated person or police may be notified.

The driver may also request guidance about a route or assistance infinding a store. Advertisements may be presented based on the driver.Coupons may also be offered. An individual, for example, looking for adry cleaner along a particular route or within a radius may be presentedwith a list of options including coupons. Advertisers may agree to payin exchange for a premium listing including better placement or furtherdetails.

Embodiments of the present invention, however, are not limited toautomobiles. For example, suitable embodiments of the present inventioncan be used in trucks, airplanes, railroad cars, boats, elevators, metrosystems, high-speed vehicles, motorcycles, and other forms oftransportation. This system may be encased in a waterproof film or boxsuch as for use in outdoor applications such as motorcycles. The systemmay also be integrated into the dashboard of motorcycles. The system mayalso be used in rental vehicles to prevent unauthorized drivers.

In any of the above suitable embodiments it may be desirable to providebiometric verification each time somebody sits in the driver's seat,periodically during driving, when requested by law enforcement, when afurther form of identification fails, such as a password, keycard, orverifiable credential, or when authorization is required to enter a tollor restricted road or area.

In any of the above suitable embodiments the biometric information maybe encrypted and transmitted, including wirelessly, to a local official,a transceiver/receiver unit, or to a satellite, cellular or otherreceiving station.

There may be different levels of credentials, such as an owner, aparent, a valet, a friend, a police officer, a tow-truck, or thedealership. The system may be programmed to respond differently todifferent credentials. Credentials may be assigned levels ofauthorization, and different levels of authorization may permitdifferent actions. Police officers, for example, may have high levels ofauthorization, permitting them to override the system or view logs fromother drivers. Valets, on the other hand, may have low authorizationlevels permitting them to drive at low speeds and restricting them from,for example, opening the trunk.

The system may be configured to interface directly with the vehiclecomputer, or may communicate through blue-tooth, other wirelessprotocols, or through the vehicle's ODBC diagnostic port or directly byinterface with the ignition or starter.

As envisioned, certain embodiments of the present invention includecross-checking a biometric identification with a valid driver's licenseand valid insurance card to control access to a vehicle. In oneembodiment, a driver would enter a vehicle, scan their driver's licenseand insurance card, and then perform a biometric identification. Thesystem would cross-check the information on the driver's license,insurance card, and biometric identification. If the cross-check wassuccessful, the car would be allowed to start. The information stored onthe driver's license and insurance card in an exemplary embodiment wouldbe stored on a tamper-resistant smart card. The biometric informationcould be cross-checked against the information stored in the smart card,or, in one representative embodiment, be used as a key to unlock anencrypted vehicle starting code stored in the smart-card.

As envisioned, in addition to cross-checking the biometric informationwith the driver's license and insurance card, substance detectors (e.g.,breathalyzer, pupil dilation/retinal scanner device, IR detectiondevice) would be used to verify that the driver is not under theinfluence of a prohibited substance.

As envisioned, one embodiment of the present invention is adapted toprevent unlicensed, uninsured, or drunk drivers from operating avehicle. By requiring a driver to verify that he has valid insurance, avalid driver's license, is not intoxicated, and is the same person whois on the insurance card/driver's license, the roads can be made safer.As a further benefit, once such a system is implemented it will reducevehicle theft since potential thieves would not be authorized driversand thus could not start the vehicle. Further, such a system wouldreduce crime, since logs created could be authenticated as accurate toprove that a particular person was in their vehicle or at a particulardestination at a certain time. Further, if a vehicle is implicated in acrime, the vehicle's logs can be examined to determine who the driverwas and where they had gone before and after the crime scene. Further,such a system will reduce drunk drivers since it can be configured toprevent drivers who are intoxicated from driving. This can be done byusing the same retinal or biometric scanner that is used for the initialbiometric identification.

The system is designed to be user friendly and easy to operate. When aperson buys a car the seller of the vehicle will grant them access. Thismay be done by performing a change of ownership command. The originalowner, or car dealer, would identify themselves to the vehicle, such asthrough the biometric or retinal scanner, and then notify the system(preferably through voice-activated commands) that they are transferringownership to a new person. They would then step out of the vehicle andthe new person would enter the vehicle to perform their biometricidentification and/or swipe their driver's license or insurance card.The system could then delete the old owner's rights and grant rights tothe new owner.

A current owner of the vehicle can also add new drivers. For example, aspouse can add their significant other. This could be performed by thecurrent owner verifying his biometric information and selecting anoption (preferably through voice activated commands) to add a newdriver. The current owner could also specify what rights the new driverwould be entitled to. For example, the rights could be restricted toparticular speeds, could restrict whether the new driver is allowed toadd additional new drivers, and may select an expiration date for thenew driver's privileges. The new driver would then sit in the driver'sseat, perform a biometric authentication, and the information would besaved to the system's memory.

As envisioned, certain embodiments of the present invention includeusing a biometric device for the dual purpose of providingauthentication of identity and performing a state test. A retinalscanner may used, for example, to identify not only who a particulardriver is, but also to assure that they are not drunk. When individualsdrink, the blood vessel patterns in their eyes may swell or change. Whenan individual is originally added to the vehicle their retinal scanwould likely capture their blood-vessel pattern in a nonintoxicatedstate. If they are later intoxicated, their blood vessel pattern wouldnot match their original, stored, blood-vessel pattern. As such, theretinal scanner could therefore be used not only for identification, butalso to determine that an individual is intoxicated. Similarly, a cameraand light can be used to perform a pupil dilation test while alsorecording the identity of the individual. The light may be the domelight or a light on the visor.

The original biometric information may also be stored on the verifiablecredential. A retinal scan or fingerprint scan, for example, could betaken at the Department of Motor Vehicles or another authorized locationand stored on the credential. This stored and verified credential couldthen be cross-checked against the biometric information obtained whenthe vehicle is started to guarantee that the driver of the vehicle isthe person who has the valid insurance and driver's license.

Where used for parental control, the system may be customized at therequest of a parent. In one embodiment, the system identifies a pin-codeor password with the parent. Any driver who fails to enter the pin-codewill be treated as a child. A parent may set hours of the day that thevehicle may be driven by entering the information on a touch screendisplay, through a keyboard, with voice activated commands, bypreprogramming the information on another computer and communicating theinformation to the system, or through a wireless communications link.The system is dynamic and can allow parents to remotely control aspectsof the vehicle. A communications link may be opened so that the parentscan talk to the driver or the parents may remotely enforce drivingrestrictions including setting a maximum speed or requiring the vehicleto follow a particular route. This may include an automated drivingsystem or providing an indicator when the child has gone off-route. Thesystem may also allow the radio to be remotely controlled or a camera tobe initiated that displays the road or passenger compartment to theparents through the wireless connection, such as by using a webcam. If aparent wishes to remotely access the system they may be required toenter a pin-code on their telephone or speak a password. If done througha computer link, they may be required to perform a biometricidentification or enter a password on their computer. Once a parent hasbeen granted remote access they may be permitted to perform any functionas if they were inside the vehicle.

FIG. 1 shows a block diagram of a driver's card identification systemand/or a system of preventing use (or unauthorized use) of a vehicle byan operator (or driver) of the vehicle according to an embodiment of thepresent invention.

As shown in FIG. 1, the system 10 includes a control module (or systemcontroller) 16, a biometric authenticator 12, a state detector 14,and/or a credential authenticator (or sensor) 18. The biometricauthenticator 12 is coupled to the control module 16. The state detector14 can be a substance detecting sensor (or detecting device) adapted toprovide a substance level in the operator to the control module 16.Here, the control module 16 is adapted to communicate a drivingrestriction to the vehicle if the substance level in the operator isabove a tolerance level or if the operator is not authenticated by theauthenticator 12.

Also, in one embodiment of the present invention, the substance level isdetermined at an extremity of the operator, the operator is alsoauthenticated at the extremity, and the extremity is selected from thegroup composed of finger, thumb, toe, ear, palm, sole, foot, hand,and/or head.

In one embodiment, the control module 16 is further adapted tocommunicate with the vehicle to permit the vehicle to start if theoperator has been authenticated by the authenticator 12 and thesubstance level in the operator is not above the tolerance level. Also,as shown in FIG. 1, the authenticator 12 may be a fingerprintauthenticator, a face recognition authenticator, a hand-geometryauthenticator, a voice authenticator, etc. In one embodiment, theauthenticator 12 includes a fingerprint sensor (or scanner), and thesubstance level in the operator is determined in-vivo at a tissue withinthe finger of the operator.

In one embodiment, the substance detecting sensor is adapted to detectan alcohol level in the operator. Here, the substance detecting sensormay include a broadband (or wideband) detector (e.g., a singlephotodiode detector) described in more detail below. In addition, asdescribed in more detail below, the substance detecting sensor mayinclude a broadband light source and a wavelength filtering systembetween the broadband detector and the light source. The wavelengthfiltering system and the broadband light being configured to direct alight beam at a specific wavelength band toward the broadband detector.In the context of the present application, the specific wavelength bandcan refer to one or more wavelengths or wavelengths ranging from onespecific wavelength to another specific wavelength. Alternatively, thesubstance detecting sensor may include a diode or a diode laserconfigured to direct a light beam at a specific wavelength band towardthe broadband detector and described in more detail below.

Referring back to FIG. 1, the credential authenticator (or sensor) 18adapted to sense a verifiable credential of the operator is coupled tothe control module 16. Here, the control module 16 is adapted to verifythat the operator authenticated by the authenticator 12 matches theverifiable credential of the operator. As shown in FIG. 1, theverifiable credential that can be sensed by the credential authenticatorincludes a driver's license, an RFID tag, a smartcard, a credit card, akey ring including an infrared (IR) adapter, and/or an under-skinimplant.

FIG. 2 shows a flowchart of process blocks associated with a driver'scard identification system and/or a system of preventing use (orunauthorized use) of a vehicle by an operator (or driver) of the vehicleaccording to an embodiment of the present invention. As shown in FIG. 2,the operator or driver enters the vehicle with the system (e.g., thesystem 10 of FIG. 1) in block 21. In block 22, the driver verifies hisdriver's license to the system. In block 23, the driver verifiesinsurance card to the system. In block 24, the driver performs biometricidentification and substance check with the system. In block 25, thesystem cross-checks the driver's license, insurance card, and biometricinformation. If the cross-check is unsuccessful, a control module of thesystem (e.g., the control module 16 of FIG. 1) communicates (or issues)a driving restriction, e.g., an ignition lockout, to the vehicle inblock 26. By contrast, if the cross-check is successful, the controlmodule communicates with the vehicle to permit the vehicle to start orto authorize ignition (e.g., issues an ignition authorized command) inblock 27. Here, the controlled vehicle may include a vehicle selectedfrom the group consisting of an aircraft, a mass transit vehicle, awatercraft, a piece of industrial equipment, and a piece of heavymachinery and equipment

FIG. 3 shows a visor mounted biometric device 30 according to anembodiment of the present invention. Here, the visor mounted biometricdevice 30 may be included in the biometric authenticator 12 of FIG. 1,and coupled with the control module 16 of FIG. 1 via a hinge with wires31.

As envisioned, an embodiment of the present invention provides anenhanced system and method for biometric and/or substance detection. Inone embodiment, a system identifies a person using biometric techniquesand also checks for the presence of substances in the body such asalcohol through the use of non-invasive techniques such as NearInfra-Red (NIR) spectroscopy, Raman Spectroscopy, PhotoacousticSpectroscopy, Scatter Changes, Polarization Changes, Mid-InfraredSpectroscopy, and/or Narrowband Detection.

An embodiment of the present invention envisions a design to integratethe two, ordinarily separate, functions of biometric identification andsubstance detection resulting in additional functionality and lowercost. Such a system may be readily capable of integration into existingand future applications for access control, improved safety, andequipment/vehicle operation.

Substances may be detected in the vascular system by measuring thespectral pattern in the Near IR range which allows quantitation ofsubstances. For example, substance detection through noninvasivetechniques may be performed by analyzing the changes in the watermolecules of the vascular system with a spectrometer.

As envisioned, other embodiments of the present invention provide asystem that includes an interface to an external hardware device or to asoftware application. The information may be provided to a multitude ofsuitable applications and/or systems as discussed above and in moredetail below. The system, when integrated with some of the suitableapplications and/or systems, could provide information to a mainprocessing function that would then perform a decision or computation.For example, the processing function could access a database todetermine whether the person is entitled to entry into a controlled areaor limit the person in the operational functionality of equipment and/orvehicles. The processing function or system could also notify a thirdparty, such as security personnel, police, or an administrator, or storethe information in a database.

As envisioned, an embodiment for the present invention includespositioning of a sensor in a strategic location and informational datatransfer to a processor which interprets the data and performs afunction based on the data, such as enforcing access restrictions of aperson. In the case of a controlled area access, the system could beinstalled near a door or other means of controlled access point such asa light curtain, optical sensor switches, motion detectors, gates, orhuman controlled check-points. In the case of operation of equipment orvehicles, the sensor could be installed on the operator's control panelfor the equipment or for vehicles, on the dash, clutch, or near the areaof the ignition starter of the vehicle. In the case of an airlinerflight deck or airplane cockpit a simultaneous reading of both pilot andco-pilot would be performed in their operational positions.

In one embodiment, the sensor may be coupled to a pad or holder forpositioning of a hand or finger. For example, a person using the systemmay place their finger into a mold or sheath. Upon input of the fingeronto or into the device, a scan of biometric data would be performed andthe data could be provided to a separate processing point whereupon thedata could be matched to an existing database and/or locally within thedevice's central processing unit with a locally stored or remotelyconnected database. In a further embodiment, the system could identifythe person based on the biometric information and determine if there aresubstances in their body. Based on this identification and/or substancedetermination, the system could perform any and all functions such ascontrol doors or access points, record the information, requireadditional information such as a PIN code, or give the user a message.The noninvasive scan can be performed at any wavelength using any methodof noninvasive scanning. An embodiment of the present invention caninclude an NIR spectroscopy scanner adapted to detect, for example, thepresence, type, and magnitude of alcohol, drugs such as THC, or glucosein the case of previously known person's diabetic condition. An analysiscould then be performed. NIR spectroscopy can detect drugs and alcoholat a range of about 1000 nm to 2000 nm. Alcohol, for example, may bedetected at the wavelengths of about 1700 nm, 1600 nm, and 1300 nm.Other drugs or substances that could alter the cognitive capabilities ofthe person could also be examined within the limits of the sensor. Theseresults could be used to determine the cognitive capability of theperson to perform the functions required either in the area ofoperation, such as a bank vault, or equipment such as a crane, or heavyequipment, or a vehicle such as an automobile, truck, bus, train orairliner. The results could further be stored in a database for futureverification including intoxication or identity. The results couldfurther be sent to a third person for manual verification, especiallywhere the identity or intoxication levels approach programmed ranges.The combined results of the sensor relating to a person's identificationand to his/her cognitive capability could be processed to allow/disallowthe access or operation of equipment or vehicles.

In a further embodiment, a simultaneous scan could be performed byconducting a source of light, such as NIR light, upon the finger andtaking the back scatter of light into a beam splitter that would feedthe biometric sensor and/or the substance sensor directly.

In another embodiment, a double beam of light could be impressed uponthe finger, for the biometric function, near the extremity and for thespectroscopy nearer the knuckle on the bottom side of the finger wherethe skin is thinner. In another embodiment, the sliding action of thefinger upon a scanning device would provide the biometricidentification, and a beam of light, such as NIR light, would be usedfor the spectroscopy measurement performed on the bottom side of thefinger nearer the knuckle.

In one embodiment, the biometric and/or substance detection system ofthe present invention is small enough to allow it to be positioned forconvenient access and strategic location functionality, yet large enoughto accept the 3 sigma case largest finger based upon populationdistribution. The electronic data interface provides an output, such asa standard USB, Ethernet, or serial plug or specialized interfaces fordedicated applications such as in automobiles post-1996 using theOBDC-II interface. Scanned and spectroscopy analyzed data may also bemade available to near processing units using blue tooth or tolocal/long distance processing units through the Internet, such as viathe IP protocol, cellular wireless or in remote locations usingcommercially available satellite communications such as GlobalStar orIridium. The raw light or data may also be transmitted, for example,through fiber optic cable for analysis at a remote or central sensor. Inremote or highly inaccessible applications the sensor could be astandalone unit including the main processor and authenticated person'sinformation in its local database. Power for the operation of the devicecould either be through the host processing unit's power supply (+3.3VDC, +5 VDC, +12 VDC, etc.), through AC (100 VAC, 115 VAC, 200 VAC, 230VAC, etc), through an on-board battery and/or AC charging and/or solarpanel charging, such as in remote or highly inaccessible applications.

There are commercially-available devices available for obtainingbiometric data for identification purposes. There are devices available,in some form of operational readiness, that can perform and processnon-invasive scans. The Iso-Chem NIR Material Analysis System, availablefrom LT Industries, Inc. is a portable NIR analyzer with remotelytriggered testing probes. The USB4000, for example, available from OceanOptics is a spectrometer responsive to 200-1100 nm. The SM241, forexample, available from Spectram Products is a compact CCD basedspectrometer designed for NIR laser applications with a range of 900 nmto 1700 nm. The OSM-100, for example, available from Newport Corporationis a portable, economical spectrometer that is responsive to from 200 nmto 1700 nm. The Sugartrac is a non-invasive glucose monitor, availablefrom Lifetrac Systems. The TouchPrint Enhanced Definition 3000 Live Scanis a portable biometric scanner and identification device, availablefrom Live Scan Products.

Also, as envisioned, an embodiment of the present invention provides amethod for combining biometric identification with substance detection.This may be performed using the system or device as described above orwith any other biometric identification system and any other substancedetection system. For example, a face scanner or retinal scanner may beused in combination with a substance detector (e.g., a breathalyzer). Inan embodiment of the method for combining biometric identification withsubstance detection, the steps of a biometric scan and a substancedetection scan are performed. Additional steps, such as activating thescan, processing the scan, comparing the scans, sending a notificationor alarm, activating a recording device, saving the raw data or theprocessed results, or performing error-checking or a further type ofscan may be performed. Additionally, the step of checking thetemperature or pulse may be performed to verify that the scan isaccurate.

FIG. 4 shows a block diagram of an enhanced biometric and substancedetection system and device according to an embodiment of the presentinvention. As shown, a sheath (or cradle) 100 (e.g., a finger cradle)with a hole at one end 120 for the insertion by an extremity of anoperator (e.g., a finger) is provided. A biometric sensor 210 and asubstance sensor 220 are included with the sheath 100. In oneembodiment, the extremity is selected from the group consisting offinger, thumb, toe, ear, palm, sole, foot, hand, and head.

In addition, the biometric sensor 210 and the substance sensor 230 arerespectively coupled to a biometric device (or authenticator) 400 and asubstance detection device 500 via leads 300. The biometric device 400and the substance detection device 500 are coupled to a centralprocessor (or system controller or control module) 700 via leads 600.The central processor 700 may then be coupled to the access controlprocessor 800, which may be coupled to an access control device orinterface 900.

Referring to FIG. 4A, in one embodiment, the enhanced biometric andsubstance detection system and device of FIG. 4 is incorporated within avehicle 100 a. In one embodiment, the vehicle 100 a is selected from thegroup consisting of an aircraft, a mass transit vehicle, a watercraft, apiece of industrial equipment, and a piece of heavy machinery andequipment. In more detail, the vehicle 100 a includes the sheath (orcradle) 100 for insertion by the extremity of the operator.

Referring to FIG. 4B, in another embodiment, the enhanced biometric andsubstance detection system and device of FIG. 4 is incorporated within atime clock system 100 b. Here, in one embodiment, the time clock system100 b is adapted to create an alert if the substance level in theoperator is above a tolerance level or if the operator is notauthenticated by the authenticator. In one embodiment, the time clocksystem 100 b also includes a time clock 101 adapted to determine a timewhen the alert is created. Also, the central processor (or systemcontroller) 700 may be adapted to communicate with a building securitydevice to permit the operator to access the building security device ifthe operator has been authenticated and the concentration of thesubstance is not above a tolerance level. In one embodiment, the centralprocessor 700 is adapted to communicate with the building securitydevice to restrict the operator from accessing the building securitydevice if the operator has not been authenticated or the concentrationof the substance is above the tolerance level. The building accessdevice may include the time clock 101 adapted to determine a time whenthe operator is permitted access to the building security device.

FIG. 5 shows another embodiment of the present invention. As shown inFIG. 5 a system for preventing use of a vehicle by an operator of thevehicle includes a system controller 570, a biometric authenticator 540,and a substance detecting device 550. Here, the system controller 570 isadapted to detect at least one biometric parameter at a first dermallocation 560 a of an operator (or at an extremity of the operator) 560of a vehicle and generate an authentication output indicating that theoperator 560 has been authenticated. Here, the first dermal location 560a of the operator 560 is a location capable of biometricallyauthenticating the operator 560 (e.g. at a fingerprint of the operatoror a location where a fingerprint of the operator 560 is at). Inaddition, the substance detecting device 550 is adapted to detect alevel of a substance in the operator 560 at a second dermal location 560b proximate to the first dermal location 560 a and generate a leveloutput.

Here, in one embodiment of the present invention, the two detectionmeasurements (i.e., the authentication and the substance detection) takeplace on cutaneous (or dermal) locations of the operator that areproximate to (possibly adjacent) one another. In the context of thepresent embodiment, proximate and/or adjacent can be referred to asclose enough to substantially preclude circumvention of the test bymeasuring the substance level of a person other than the one beingauthenticated.

In addition, referring still to FIG. 5, the system controller 570operates in response to the authentication output and the level outputto selectively restrict use of the vehicle if the operator 560 is notauthenticated or the detection output is above a preselected tolerancevalue.

Also, in one embodiment, the substance detecting device 550 includes alight source and a single broadband detector described in more detailbelow. Here, a surface (or platform) of the substance detecting device550 that is coupled to both the light source and the single broadbanddetector contacts the second dermal location 560 b and has an index ofrefraction that corresponds (or is identical or substantially identical)to that of the second dermal location 560 b to reduce or eliminatespecular light (i.e., light that did not penetrate into the skin).

As envisioned in embodiments of the present invention, radiation passingthrough a sample is attenuated depending upon the path length traveledby the radiation and the strength of absorptions at various individualwavelengths for constituents within that particular sample. Recordingand mapping the relative strength of the absorption versus wavelengthresults in a unique absorption spectra for that particular sample.

One application area for spectroscopy is the measurement of tissueattributes or analytes noninvasively. A specific application is themeasurement of analytes, such as ethanol, noninvasively for subjects tobe screened for substance abuse.

Near-infrared radiation (NIR) offers distinct advantages formeasurements in tissue spectroscopy. Optical path lengths greater thanone millimeter are readily achieved in the NIR in the therapeutic windowof the electromagnetic spectrum. However, influences that interferingchemical species have on the accuracy of analytical determinations(e.g., determinations of ethanol) are issues that need to be resolved.In the context of the present application, the issues that need to beresolved can be referred to as backscatter and selectivity, or theextent to which a method can be used to determine particular analytes inmixtures or matrices without interference from other components ofsimilar behavior.

That is, the primary source of noise is the light scatter that does notbear the complete signature of ethanol in the blood. Human skin hasseveral layers: epidermis, dermis and subcutaneous tissue. Each layerhas its own wavelength-dependent absorption and scattering properties.The light undergoes both forward and backscatter as it penetrates theskin, interacts with blood, and comes out. Further complications arisewhen the skin is not at a constant angle with respect to illuminationand collection from sample to sample. Location of the part of the handmay also matter. Thus, a system should reduce or eliminate the amount ofinitial light scattering by using optical coupling and/or reducingdifferences in refractive index and/or reducing or eliminating detectionof any light that is scattered before reaching the tissue containing theanalyte.

Moreover, with respect to detection of the light that is reflected afterreaching the tissue containing the analyte, spectral data arising fromspectroscopic analysis provides a wealth of detailed information aboutthe identity, structure, concentration or constituents of samples.Spectral data derives from the detected and recorded energy change of amolecule through the emission, scattering, or absorption of a photon. Inparticular, atoms within a molecular species vibrate back and forthabout an average distance. Absorption of light by an atom at anappropriate energy causes the atoms to become excited, elevating theatom to a higher vibration level. The excitation of the atoms to anexcited state occurs only at certain discrete energy levels, which arecharacteristic for that particular molecule. Infrared absorptionspectroscopy is particularly useful for performing this type ofanalysis. In absorption spectroscopy, the net absorption of incidentradiation at various wavelengths is measured. However, the system shouldbe able to detect levels of a particular analyte and discriminatebetween that analyte and others that might have similar characteristics.

As envisioned and to resolve the above described issues, an NIRreflectance instrument was developed to include an illumination sourceand a spectrometer described in more detail above. The instrumentutilized near-infrared radiation in the specific wavelengths rangingfrom about 1300 nm to about 2400 nm; more specifically, from about 1400nm to about 1500 nm, from about 1650 nm to about 1750 nm, and/or fromabout 2200 nm to about 2400 nm. In one embodiment, a specific wavelengthband at about 1450 nm is utilized. These wavelength ranges are of primeinterest for making noninvasive alcohol measurements because theycontain combination and overtone bands for a wide variety of chemicalspecies including alcohol and other organic molecules present in tissue.The NIR spectrum of ethanol has pronounced features in these wavelengthranges due to bands of C—H bends and C—H stretches of the alcohol andother organic molecules and/or the combination band of the 0-H bends and0-H stretches of alcohol and other organic molecules.

These wavelength ranges should also be less influenced by tissuescattering effects when compared to higher wavelength regions, as theeffects of tissue scattering increase with wavelength. This hassignificant implications in tissue measurements because scatteringeffects can cause substantial spectral variability both within andbetween human subjects.

Referring to FIG. 6, a spectrum of 100% ethanol with a 1 mm samplingpath at specific wavelengths ranging from 800 nm to 2400 nm werecollected using a research grade NIR spectrometer. As can be derivedfrom FIG. 6, the specific wavelengths ranging from about 1300 nm toabout 2400 nm are of interest. Also, the specific wavelengths rangingfrom about 1400 nm to about 1500 nm, from about 1650 nm to about 1750nm, and/or from about 2200 nm to about 2400 nm are of particularinterest.

As shown by the research grade NIR spectrometer data in FIG. 7, theresearch grade NIR spectrometer is capable of distinguishing 0.10%,0.08%, 0.06%, and 0.04% ethanol in water at the specific wavelengthsranging from about 1400 nm to about 1500 nm. As can be derived from FIG.7, the specific wavelength band at about 1450 nm is of particularinterest.

In addition, as shown in FIGS. 8 and 9, the research grade NIRspectrometer is capable of distinguishing 0.10%, 0.08%, 0.06%, and 0.04%ethanol in water at the specific wavelengths ranging from about 1650 nmto about 1750 nm, and at specific wavelengths ranging from about 2200 nmto about 2400 nm. In FIGS. 8 and 9, the specific wavelength bands atabout 1700 nm and at about 2300 nm are of particular interest.

To investigate ethanol sensitivity and, more importantly, selectivity,samples should be constructed containing ethanol, glucose, creatinine,urea, water, and microspheres. The microspheres (e.g., polystyrenemicrospheres) provide an optical scattering medium that yields areflectance signal whose intensity is similar to that of red-bloodcells. Thus, the samples provide conditions that will mimic blood undera variety of circumstances. The concentration ranges of the analyte ofinterest, ethanol for example, and those of possibly interferinganalytes should mirror those observed in a healthy subject population(i.e., human and/or biological ranges). The whole universe of samples ofthe concentrations should then be reduced using a suitable statisticalmodeling, such as a Latin hypercube of a suitable level. In oneembodiment, a set of a 7-level Latin hypercube design is used to providemaximum inter-analyte correlations with manageable sample sizes.

Intensity spectra are then collected from the samples (or in-vitro) ofvarious concentrations. The collected spectra are then analyzed todetermine the wavelength ranges that are needed and the wavelengthranges that can be eliminated for proper ethanol analysis. Human (orin-vivo) testing should then be performed to validate the statisticalmodeling and design with respect to ethanol, the model should be able todetect ethanol in blood down to about 0.05% with an accuracy ofpreferably plus or minus 0.02%, more preferably plus or minus 0.01%.

The validated statistical model for analyzing the data then provides thespectral bands for the sensor. As envisioned according to one embodimentof the present invention, three (3) non-overlapping wavelength regionsin the NIR ranges are utilized. Each wavelength region should have from3 to 4 non-overlapping sub bands. Each of these wavelength bands hasabout a 25 nm bandwidth.

FIG. 10A shows an optical substance detector configuration according toan embodiment of the present invention. In more detail, the detectorincludes a light source (collimated broad-band IR source) for providinga light beam having multiple wavelength bands (shown as multiple coloredrays). The light beam is directed to a filter adapted to isolate adesired or specific wavelength band (or sub-band). The isolated lightbeam is then directed to a condenser and passes through an input fiberbundle (or plastic light guide or suitable light guide) to a glassplatform (or finger cradle or index finger slab) in which a test sample(e.g., a finger or an extremity selected from the group consisting offinger, thumb, toe, ear, palm, sole, foot, hand, and head) is placedthereon. In one embodiment, the glass platform has an index ofrefraction that corresponds (or is identical or substantially identical)to that of the test sample to reduce or eliminate specular light (i.e.,light that did not penetrate into the skin of the test sample). Inaddition, the glass platform can be formed of a 1 mm thick fused silicaglass, preferably with a non-reflective coating. The light beam that hasbeen reflected (or diffusely reflected) from the test sample (e.g., thefinger) is collected by a collector fiber bundle (or plastic light guideor suitable light guide) coupled to the glass platform. A detector isthen used to detect the light (or light intensity) diffusely reflectedback from the test sample and collected by the collector fiber.

Alternatively, FIG. 10B shows an optical substance detectorconfiguration according to another embodiment of the present invention.In more detail, the detector here includes a light source 1200 forproviding a light beam (or beams) having multiple wavelength bands(shown as multiple rays). The light beam(s) is (or are) directed to atest sample 1210 (e.g., a finger or an extremity selected from the groupconsisting of finger, thumb, toe, ear, palm, sole, foot, hand, andhead). In one embodiment, the light source 1200 has a parabolic orelliptical reflector to focus or direct the light beam. The lightbeam(s) that has been reflected (or diffusely reflected) from the testsample (e.g., the finger) is passed through a filter 1220 adapted toisolate a desired or specific wavelength band (or sub-band). A detector1230 (e.g., a single broadband detector) is then used detect the light(or light intensity) diffusely reflected back from the test sample andfiltered by the filter 1220. As such, in FIG. 10B, the filter 1220 isshown to be disposed closer in distance to the detector 1230 than to thelight source 1200. Here, in FIG. 10B, since the light beam(s) from thelight source 1200 is not filtered until it has been reflected back fromthe sample 1210 (i.e., the filter 1220 is at the detector end), arelatively large amount of light is directed to and diffusely reflectedback from the sample 1210.

The present invention, however, is not limited to the filter positioningembodiments of FIGS. 10A and 10B. For example, to increase wavelengthselectivity and/or to reduce signal to noise ratio, an embodiment of thepresent invention envisions configuring a first filter to be disposed atthe light source end (e.g., the filter of FIG. 10A), and a second filter(e.g., the filter 1220) to be disposed at the detector end.

In one embodiment, the light source can be an incandescent light source,such as tungsten-halogen lamp, xenon arc lamp, mercury arc lamp, LED(s),and/or diode laser(s), which has abundant IR. In one embodiment, thelight source is collimated prior to filtering using a narrow bandpassoptical filter. The filter adapted to isolate a desired or specificwavelength band (or sub-band) can be part of a filter wheel that can berotated to bring different filters in position. This allows collectingdata from multiple wavelength bands. The condenser optics are used tofocus light into the fiber, which carries the light to the opticaltissue (e.g., the finger). The collector fiber collects the scattersignal from the tissue and carries it to the detector.

Also, various suitable types of fiber bundles may be used, such as aring type light guide, a straight type light guide, a bifurcated typelight guide, etc. In addition, instead of using fiber bundles, anembodiment of the present invention envisions the use of other suitabletypes of light guides, such as plastic light guides.

In one embodiment, an optical substance detector includes a light sourceincluding a halogen lamp and a fiber optic bundle attached to thehalogen lamp to illuminate a test sample (e.g., an area of the testsample) with a configured wavelength filtering system. The wavelengthfiltering system can include various suitable types of filter, such as,interference, band pass, absorption, dichroic, monochromator grating,etc. The wavelength filtering system according to one embodiment isdisposed closer in distance to a detector (e.g., a single broadbanddetector) than to the light source. The desired wavelength bands arereflected back to the detector. Through an evaluation involving astatistical modeling analysis, the test sample's blood alcoholconcentration (BAC) is determined with respect to a legal limit tooperate a vehicle and, if the BAC is not within the legal limit, thevehicle is disabled. In one embodiment, the statistical modeling is aLatin hypercube of a suitable level. However, the present invention isnot thereby limited. For example, any suitable multivariate statisticsor multivariate statistical analysis in statistics that can be used todescribe a collection of procedures which involve observation andanalysis of more than one statistical variable at a time can be used.

Another embodiment of the present invention provides a light source(e.g., a diode laser) at a specific (single) wavelength band in theinfrared (IR) or near IR wavelength range(s) and a broadband detectorfor non-invasive and/or in-vivo testing of a concentration of asubstance in a tissue of a person. The substance can be alcohol, morespecifically, ethanol, and the tissue can include a person's blood.

In more detail, FIG. 11 shows ethanol and water optical absorption from800 to 2400 nm. As such, an embodiment of the present invention providesan optical method for non-invasive and/or in-vivo ethanol testing thatexploits the difference in optical absorption between ethanol and water,and, because blood is primarily formed by water, a concentration ofethanol in the blood can be determined. As in all manner of absorptionspectroscopy the amount of light absorption at a specific wavelength isused to positively identify the chemical compound in the solvent. Agiven aliquot of water and ethanol will absorb less light at certainwavelengths then an equivalent aliquot of water alone. At otherwavelengths the phenomenon is reversed and the ethanol water mix willabsorb more light.

It is possible to make these measurements using a variety oftechnologies at several different wavelengths as shown in FIG. 12. Inone embodiment of the present invention, a wavelength at about 1000 nm,a wavelength at about 1310 nm, a wavelength at about 1550 nm, and/or awavelength at about 1900 nm were selected, as regions (or regimes) whereethanol is more transmissive, (less absorptive) than water. Spectralregions at about 904 nm, about 1700 nm, and about 2300 nm were alsoselected, as regions (or regimes) where ethanol is less transmissivethan water.

Referring to FIG. 13, a first distinction of the technologies that maybe used to make the above described measures is the type ofillumination, narrow-band or broadband. Most absorption spectroscopytechnologies use a white light or broadband light source and then useeither an interferometer or diffraction grating to “sort” the light intospectral bins. These systems have some common elements, coupling offinger to illumination either with a fiber or directly (FIGS. 13 and 14)and the final optical signal detection technology, which will becomposed of either a linear CCD array or a photodiode detector.

In more detail, FIG. 13 shows illumination is on the left hand side.Here, the illumination is provided from a self-contained light source,bulb, blackbody etc. 110 a or a fiber which is coupled to a remote lightsource 110 b. To the right of the light source 110 a, 110 b is acollimating lens 130 that renders parallel the light as it traversesthrough or into a finger (e.g., middle finger) 140 to a reimaging lens150, which focuses the “sampling beam” onto a fiber 120 a, 120 b that isconnected to a diffraction grating spectrometer or some type ofinterferometer.

FIG. 14 shows a schematic of a finger sensor with integral fingerprintscreen according to an embodiment of the present invention. The twoports (Fiberoptic Ports) can be used for either fiber coupling optics ordirect detection (i.e. a broadband detector or an InGaAs detector couldbe installed directly in one of the ports) to allow light from a lightsource (e.g., via another one of the light port) to be detected via,e.g., diffuse reflectance. That is, in FIG. 14, an incident beam oflight can be directed from a first side of the finger toward a secondside of the finger, and the broadband detector can be configured tomeasure the portion of the incident light beam transmitted through aportion of the tissue and reflected back to the first side of thefinger. Also, other sensors, e.g., temperature, surface contaminant,etc., can be installed on the bottom of this unit.

FIG. 15 is a schematic of a photodiode with a transimpedance amplifierand thermal control as envisioned according to an embodiment of thepresent invention. The photodiode detector schematic demonstrates theextant detector system. An InGaAs or Si photodiode is coupled to atrans-impedance amplifier. The detector is thermoelectrically cooledwhile an integral thermistor monitors the temperature. However, thepresent invention is not thereby limited. For example, instead of usingan InGaAs detector as the detector (or the infrared detector), otherembodiments of the present invention can use a PbS detector, a PbSedetector, an InAs detector, an InSb detector, a HgCdTe detector, etc.

As discussed above, absorption spectroscopy can be used toquantitatively identify a substance through the application ofLambert-Beer's law, usually referred to as Beer's law, as shown by theequation below.

${A\left( \lambda_{i} \right)} = {- {\log\left( {\frac{I\left( \lambda_{i} \right)}{{Io}\left( \lambda_{i} \right)} = {\sum\limits_{k}\;{{\alpha_{k}\left( \lambda_{i} \right)} \cdot C_{k} \cdot d}}} \right.}}$

where, the quantity of a substance A is proportional to the log of theratio of the intensity, I, as a function of wavelength pre and postabsorber. Which in turn is a function of the mass path d and theabsorption coefficient α. These quantities are all wavelength dependentso the usual approach is to take spectral measurements over manywavelengths, as seen in FIG. 11, which covers from 800 to 2400 nm.However, a task at hand was to exploit these differences in absorptionspectra to create a sensor system that can detect the presence ofethanol in the human via tactile contact. As intoxication can resultfrom small levels of ethanol, e.g., blood alcohol concentration (BAC) of0.05% and above, the detection requirements should be capable ofdetecting such concentrations.

In one approach, interferometry at 2300 nm was used to sort light. Inthis approach, a movable mirror is used to create a two-beaminterference pattern that creates a time modulated signal on adetection. In one embodiment of the present invention, an alternativeinterferometer was envisioned. In this alternative interferometer, thespatial heterodyne spectrometer (SHS), instead of a time varyinginterference pattern, an SHS would produce a spatially varyinginterference pattern that would be imaged onto an InGaAs array detector.

In more detail, FIG. 16 shows a SHS schematic in which a fiber is usedto couple the SHS to the “finger slot” via a fiber optic. The pathlength difference created by the beamsplitter (BS) and Grating 1 andGrating 2, G1 and G2 respectively created a linear fringe pattern on thedetector. An FFT would be used to convert the signal into intensityversus wavelength.

A common light sampling/sorting technique is to use optical filtersdesigned to transmit a specific wavelength of light. A rotating wheel orslider can be used to change the filter in the light path sampling atdifferent wavelengths. FIG. 18 shows a filter slider that can be used tochange the filter in the light path sampling at different wavelengths.Alternatively, static filters can be used to replace the tunablefilters. A static filter is a filter whose transmitted wavelength can bealtered by changing an applied electrical voltage. In both cases theoptical coupling is the same as shown in FIG. 17. That is, FIG. 17 showsthe use of a filter, tunable or static, to sample light. The input fibercouples light from the finger to the filter. Post-filter the “sorted”light is focused on a photodiode detector.

One embodiment of the present invention includes a diffraction gratingspectrometer. Referring to FIG. 19, the spectrometer is shown to be afiber optic spectrometer having a first mirror (Focussing mirror), asecond mirror (Collimating mirror), a grating (Grating), a slit (Slit,mode stripper), a connector (SMA connector), and a detector (Detector)that are all coupled to an optical bench. Here, the detector is a linearInGaAs array detector having a linear array of InGaAs photodiodes.However, the present invention is not thereby limited, and any ofvarious suitable spectrometers having a high single-to-noise ratio maybe used. Here, a broadband fiber coupled light source was used toilluminate a cuvette that was filled with varying solutions of varyingethanol concentrations. Entire spectra from 1100 nm to 1700 nm werecollected and a portion of which is shown in FIGS. 20 and 21. As shownby the spectrometer data in FIG. 21 having a wavelength range from 1280nm to 1320 nm, the spectrometer of FIG. 19 is capable of distinguishingfrom 1% to 40%, but does not have enough resolution for distinguishingfrom 0 to 1%. That is, while ethanol detection was achieved it was notaccurate enough to detect the from 0 to 0.1% level that might be foundin the body of an intoxicated individual.

To improve system sensitivity, a hybrid embodiment was envisioned. Thatis, in order to increase system sensitivity, a narrowband laser wasselected as a replacement light source, using the data collected fromthe broadband source testing to identify appropriate wavelength regimesin which to operate. That is, as envisioned, an embodiment of thepresent invention includes a diode laser at about a 1310 nm band. Here,the diode laser at the 1310 nm band is used to illuminate the source andthe NIR spectrometer would detect and isolate the ethanol signature.FIG. 22 shows a full spectrum, laser illumination of the embodiment.FIG. 23 shows NIR spectrometer data showing a statistically invalid butintriguing measurement of ethanol concentration versus observedintensity at about 1310 nm. That is, the NIR spectrometer observationsof FIGS. 22 and 23 were not statistically significant. As such, a moreaccurate method was needed.

As such, while ethanol detection was achieved by the diffraction gratingspectrometer of FIG. 19, it was not accurate enough to detect the 0-0.1%level that would be found in the body of an intoxicated individual.While not ultimately successful, these observations did indicate thatthe use of a narrowband source (or narrow band light source) can beutilized to detect ethanol.

In addition, it was realized that in the case of a narrowband source thespectrometer was a source of noise. As such, in another embodiment ofthe present invention, the spectrometer was replaced with a broadbanddetector or a single 3 mm diameter InGaAs photodiode detector (EOSystems). The 3 mm diameter InGaAs photodiode detector has a very lownoise and is thermoelectric (TE) cooled. This created a very simpledetection system involving a detector and a source, and no light sortingwas needed.

Using a narrow band source abrogates the need for any post-sample lightsorting technology, a spectrometer and/or a linear array of photodiodedetectors. That is, the sample under consideration is illuminated withmonochromatic and narrowband (typically a few nanometers wide) lightfrom either a laser or monochrometer. A single broadband detector (e.g.,a single photodiode detector) is used to measure the amount of lightthat is transmitted through the sample; the amount of “absorber species”within the sample under test is calculated using:I(λ)=I _(o)(λ)e ^(−α(λ)L)where Io is the incident illumination of the sample, I is the observedtransmitted intensity, α is the absorption co-efficient as a function ofwavelength and L is the mass path length. Optical probing of the samplerequires illumination either through the sample or of a uniform andstandard volume, transmissive and/or reflective techniques can be useddepending upon the sample involved.

Also, FIGS. 24A, 24B, and 24C show sample interrogation methods using anarrowband illuminate and photodiode detector. FIGS. 24A, 24B, and 24Cdemonstrate transmission, reflection and variable path lengths through atissue (e.g., a finger). Collimating and re-imaging optics would be usedto render parallel light from the source and to image the collimatedbeam onto the photodiode after passage through the sample.

In more detail, FIG. 24A shows an incident light beam directed from alight source (lamp) to strike a mirror to double a mass path length ofthe portion of the incident light beam transmitted through the tissue.Due to effect of light scattering (e.g., with red blood cells), thismirror reflecting transmission approach in FIG. 24A may not be suitablefor use with blood or finger sample(s), but this approach may still workwith other relatively low light scattering samples (e.g., urine, saliva,water, etc.).

FIG. 24B shows an incident light beam directed from the light source(lamp) to a first side of the tissue, and a broadband detector (e.g., asingle photodiode detector) configured to measure a portion of theincident light beam transmitted through the tissue from a second side ofthe tissue. In FIG. 24B, the second side is opposite to the first side.Again, due to effect of light scattering (e.g., with red blood cells),this direct transmission approach in FIG. 24B may not be suitable foruse with blood or finger sample(s), but this approach may still workwith other relatively low light scattering samples (e.g., urine, saliva,water, etc.).

FIG. 24C shows an incident light beam directed from a first side of thetissue toward a second side of the tissue, and a broadband detector(e.g., a single photodiode detector) configured to measure the portionof the incident light beam transmitted through a portion of the tissueand reflected back to the first side of the tissue. In FIG. 24C, e.g.,due to the relatively large sampling surface area, this diffusereflectance approach is likely to be suitable for use with blood orfinger sample(s) even with light scattering (e.g., with red bloodcells), and may also work well with other relatively low lightscattering samples (e.g., urine, saliva, water, etc.).

Also, in one embodiment, absorption spectroscopy with a narrowbandsource is performed with a monochrometer, which is essentially a gratingspectrometer with an input and exit slit. FIG. 25 shows detailedoperating principles of a monochrometer. That is, in FIG. 25, light (A)is focused onto an entrance slit (B) and is collimated by a curvedmirror (C). The collimated beam is diffracted from a rotating grating(D) and the dispersed beam re-focused by a second mirror (E) at the exitslit (F). Each wavelength of light is focused to a different position atthe slit, and the wavelength which is transmitted through the slit (G)depends on the rotation angle of the grating. While the scanningmonochrometer of FIG. 25 would work for the ethanol detection problem,its bulk and mechanical motion make it impractical as a source forvehicular based ethanol detection.

As such, an embodiment of the present invention provides an enhancedsystem and method for ethanol detection. Here, the ethanol sensor uses adiode laser for illumination and a InGaAs photodiode as a receiver. Thissystem is entirely or substantially passive yet retains spectral agilityas the laser is tunable by changing the system temperature. Initiallythe spectral region around 1310 nm was selected as it has a largedifference in absorption between ethanol and water as well as beingaccessible to lasers developed for the telecommunication industry. Thediode laser can be composed of a diode selected from the groupconsisting of a double heterostructure laser diode, a quantum well laserdiode, a distributed feedback laser diode, a vertical cavity surfaceemitting laser (VCSEL) diode, and a vertical external-cavitysurface-emitting laser (VECSEL) diode.

Referring to FIG. 26, an ethanol sensor apparatus according to anembodiment of the present invention includes a diode laser mounted withintegral thermoelectric cooler (TEC) and thermistor monitor connected toa PID temperature controller and a laser diode driver system. Inaddition, the sensor may include some collimating and beam expandingoptics between the diode laser and a cuvette adapted to increase a masspath. Here, the cuvette is placed between the diode laser and abroadband detector (e.g., a single InGaAs photodiode detector). That is,as a comparison, in the hybrid approach described above, the broadbanddetector is replaced with a fiber optic coupling cable that is attachedto the entrance port of a NIR spectrometer.

In more detail, the ethanol sensor according to one embodiment of thepresent invention includes a laser diode mount with an integralthermistor and TE cooler. A laser diode driver was used to operate alaser diode in constant power output mode. The laser diode is an AlGaAslaser in a 18 5.6 mm package, which provides a stable single modetransverse mode oscillation at a nominal wavelength of 1310 nm and a CWlight output of 10 mW. A spectrometer was used to tune the laser diodein temperature until an output wavelength of 1310 nm was achieved.Temperature of the laser diode to maintain 1310 nm output was controlledto an accuracy of 0.002 degree C. using a TE temperature controller.

A 25.4 mm diameter F/1 Plano-convex lens approximately one focal lengthfrom the laser diode emission surface is used to create a beam ofcollimate light that is then diffused by two 25.4 mm diameter pieces ofopal glass. This creates a source of nearly lambertian illuminationabout 10 mm in diameter. A neutral density filter can be used to lowerthe intensity of the illumination as required. Two 10 mm cuvetteholders, which have been epoxied together, are used to hold thewater/ethanol mixture with a 20 mm sample path length. Both cuvettes areclamped into a cuvette holder.

After passing through the sample in the cuvette the collimated/diffusedlight is incident on the active surface of a 3 mm InGaAs photodiodedetector. An integral TE cooling and a dual gain FET transimpedanceamplifier is used to measure the optical intensity post sample. Whenoperated at −30° C. this detector has a NEP of <2.0×10-14 W/(Hz)^(1/2)with a responsivety of 0.9 A/W at 1310 nm. A 16-bit national instrumentDAQ card is used to monitor the output of the detector and digitize theresulting data for further analysis.

The following bench tests illustrate the present invention in moredetail. However, the present invention is not limited by these benchtests.

While the components and configuration of the successor bench testsystems changed over time and when used at different wavelengths, itgenerally includes a laser module (whose wavelength could be altered bythe replacement of the internal diode and subsequently fine-tuned viatemperature control), collimating optics, diffusing optics, focusingoptics, neutral density filter(s), apertures, a section to firmly holdsamples in place, and a broadband or high performance photodiodedetector operated with a thermoelectric cooler for stabilizing, a dualgain FET input transimpedence amplifier, and a bipolar power supply.

Of note during the bench test system testing was the need to completelyisolate the sample(s) from the possibility of movement or change inabsolute position as well as the need to expand the light beam size wellbeyond that of the clear aperture of the photodiode (overfill) so thatany vibration in the system would not impart a change in measuredintensity. Also, it became evident during testing that, in order toremain stable (not oscillate) the laser needed to be operated at a“sweetspot” which was generally towards the middle of its power range;further the laser had to be operated in constant power mode as opposedto constant current.

Potential cross-contamination of samples was avoided by using dedicatedsyringes and beakers for each concentration. Potential variations causedby temperature gradients within an individual sample were avoided byreusing the same aliquot of each concentration as opposed to using asubset of a greater size of the same sample concentration.

Initial ethanol aliquots were prepared with concentrations varying from0.1% vol to 40% vol. FIG. 27 shows the transmission intensity at a 1310nm band for each sample. The initial results show a surprisingcorrelation with Beer's law; however, FIG. 28 shows the results for the0-0.1% region (or regime) did not correspond to Beer's law, and in factwere too noisy to use. That is, FIG. 27 shows the ethanol measurements0-40% at 1310 nm. The calculated error bars were too small for the plot.However, FIG. 28 shows low concentration ethanol measurements with 1sigma error bars. These results are not statistically valid.

After re-engineering the sample holder and altering the collimatingoptics to create a system less susceptible to vibration, new data werecollected as shown in FIG. 29. FIG. 29 shows statistically significantethanol measurements at the 1310 nm band. The odd behavior (non-Beer's)at 0.05% may not be an artifact and instead may be a real non-linearphenomenon.

The data in FIG. 29 shows the apparent non-linear, response of ethanolto the 1310 nm laser light. This dramatic effect may be used to identifyalcohol content below 0.1%. An additional refinement should be used toclearly discriminate 0% ethanol from high concentrations of ethanol(0.1%); absorption measurements at a second wavelength will be used forfurther systemic refinements.

While the potential efficacy of this spectroscopic technique wasdemonstrated at the 1310 nm band, a simultaneous measurement of the samesample at a second wavelength should be made for accurate determinationdue to the non-linear nature of the response at the 1310 nm band.

In summary, it has been demonstrated that the highly non-linearabsorption of ethanol in the NIR region of the spectrum, specifically1310 nm, may be used to identify quantities of ethanol consistent withBAC of 0.05% or higher. The one caveat is that to enhance quantitativedetermination of ethanol at 0% and 0.1%, a second wavelength should beused; further ethanol absorption in this second wavelength region (orregime) should have slightly different optical absorption than at the1310 nm region (or regime) used previously. The efficacy of using diodelasers as a narrowband source to detect ethanol without any lightdispersing technology was also demonstrated. It should be possible toconstruct an “ethanol sensor” utilizing two or more diode lasers and asingle cooled and amplified InGaAs photodiode to detect small quantitiesof ethanol in solution and in-vivo.

In view of the forgoing and as envisioned in one embodiment of thepresent invention, a substance sensor device includes two lasers, one ata 1310 nm band and another at another wavelength band that are coupledtogether via a fiber mixer. As shown in FIG. 30, each laser is packagedin a 14 pin “butterfly” package with an integral fiber optic pigtail.The laser unit is composed of the laser diode, an integral photodiode tomonitor laser output, a thermistor and TEC to stabilize lasertemperature. A fiber collimating optic at the “finger slide” is alsoincluded to collimate the light incident on the finger, and thenpost-finger optics are used to re-image the collimated beam onto anintegral InGaAs photodiode/pre-amp system with integral temperaturecontrol. A 12-bit DAC is provided to digitize the analog photo-diodeoutput into a digital “word” accessible by any number ofmicrocontrollers/microprocessors.

In more detail, FIG. 30 shows a schematic of a butterfly packaged diodelaser with integral fiber optic pigtail, and FIG. 31 shows two diodelasers with pigtails, each at a distinct wavelength. In FIG. 31, thelasers are mixed into a single fiber via a fiber mixer.

As envisioned, an entire substance sensor system according to anembodiment of the present invention is monitored and controlled by amicrocontroller. In one embodiment, this system is designed to be aGO/NO-GO device and not a precision measure of BAC. As such, the systemmay further include a statistical model to ensure device efficacy.

Also, in view of the forgoing and as envisioned, suitable embodiments ofthe present invention provide a system designed to prevent anintoxicated individual from operating a vehicle or other device, whetherit is a car, boat, plane, bus, heavy equipment, or entry point. Inaddition, suitable embodiments of the present invention provide a systemto reduce theft prevention. Through the use of biometric fingerprintscanning technology, the system is designed as a theft-deterrent whichprevents unauthenticated individuals from operating a motor drivenvehicle. One representative embodiment provides a system that is adaptedto verify that the person being tested by the system for intoxication isactually the driver of the vehicle.

In addition, suitable embodiments of the present invention can beapplied to a rental car fleet to reduce the risk of a driver receiving aDUI, wrecking their vehicle in an alcohol related incident, and/ortheft.

Other embodiments of the present invention can be applied to an aircraft(e.g., to reduce the risk of hijackings and/or other suitable aviationrisks); to a mass transit vehicle (e.g., bus, locomotive, trolley bus,taxicab, etc. to ensure that a vehicle's operator is sober and/orauthorized operator of that vehicle); to a watercraft (e.g., boat,cargo, passenger, tankers, ocean going ships, etc.), and/or to aindustrial equipment (e.g., heavy construction equipment, such as dumptrucks, cranes, tractors, forklifts, etc., industrial machinery such asconveyor systems, large machinery, presses and any other suitable pieceof large industrial equipment where human/operator error could result inloss of life or damage to property).

Moreover, certain embodiments of the present invention can be used toincrease and/or ensure building security (e.g., incorporated with a timeclock). These embodiments utilize authentication (e.g., fingerprintauthentication) to allow an individual to gain entry to a building orroom within a building, and/or are adapted to include detection ofillegal or controlled substances to prevent security breaches,industrial accidents and other incidents where intoxication of a workercould lead to an accident.

In more detail, FIG. 32 shows a block diagram of a system forcontrolling a vehicle given to a third party, for in-vivo measurement ofa concentration of a substance in a tissue of a person, and/or forpreventing use of a vehicle by an operator of the vehicle according tocertain embodiments of the present invention. As shown in FIG. 32, thesystem 1000 includes a control module (or system controller) 1016, abiometric authenticator (or fingerprint detector) 1012, a substancedetecting sensor (or detecting device or alcohol level detector) 1014,and/or an identity board 1018. The biometric authenticator 1012 iscoupled to the control module 1016 via a bus (e.g., via I2C Comm), andthe identity board 1018 is also coupled to the control module 1016 via abus (e.g., I2C Comm). The substance detecting sensor 1014 can be asubstance detecting sensor adapted to provide a substance level in auser (e.g., the third part, the person, the operator, etc.) to thecontrol module 1016 via a bus (e.g., via I2C Comm). Here, the controlmodule 1016 is adapted to communicate a driving restriction to thevehicle if the substance level in the operator is above a tolerancelevel or if the operator is not authenticated by the authenticator 1012.

Also, in one embodiment of the present invention, the substance level isdetermined at an extremity of the operator, the operator is alsoauthenticated at the extremity, and the extremity is selected from thegroup composed of finger, thumb, toe, ear, palm, sole, foot, hand,and/or head.

In one embodiment, the control module 1016 is further adapted tocommunicate with the vehicle to permit the vehicle to start if theoperator has been authenticated by the authenticator 1012 and thesubstance level in the operator is not above the tolerance level.

In one embodiment, the substance detecting sensor 1014 is adapted todetect an alcohol level in the operator. Here, the substance detectingsensor 1014 may include a broadband detector (e.g., a single photodiodedetector). In addition, the substance detecting sensor may include adiode laser configured to direct a light beam at a specific wavelengthtoward the broadband detector.

In addition, FIG. 32 shows that the control module 1016 is coupled to auser count switch, a program mode switch, a calibration mode switch anda display, and the identity board 1018 is coupled to a vehicle bus andother vehicle system.

FIG. 33 shows a flowchart of process blocks of system logics forcontrolling a vehicle given to a third party, for in-vivo measurement ofa concentration of a substance in a tissue of a person, and/or forpreventing use of a vehicle by an operator of the vehicle according tocertain embodiments of the present invention. As shown in FIG. 33, thesystem logics can be operating either in a calibration mode or a runmode. In the calibration mode, the system logics determine if acalibration switch is turned on. If the calibration switch is turned on,the system logics display user count switch number (that may change) inblock 1021. In block 1022, the system logics read user countidentification number. In block 1023, the system logics poll the fingersensor identification and store in a persistent memory (e.g., anEEprom). In block 1024, the system logics read alcohol detection sensorand store the reading in the persistent memory as reference for a user(e.g., the third party, the person, the operator, etc.), and return tothe run mode in blocks 1025.

In the run mode, the system logics poll the fingerprint sensor in block1031. Here, if the finger of the user is not on the fingerprint sensor,the system logics return back to block 1031. If the finger of the useris on the fingerprint sensor, the system logics determine identificationof the user from the persistent memory in block 1032.

The system logics then determine if the user is recognized. If the useris not recognized, the system logics disable the vehicle in block 1033.If the user is recognized, the logics start alcohol detection in block1034.

If the BAC limit is exceeded, the system logics then determined if thesystem override is on. If the system override is not on, the systemlogics move to block 1033 to disable the vehicle. By contrast, if thesystem override is on or the BAC limit has not been exceeded, the systemlogics log this data in block 1035, and enable the vehicle to start inblock 1036.

FIG. 34 shows a block diagram of another system for controlling avehicle given to a third party, for in-vivo measurement of aconcentration of a substance in a tissue of a person, and/or forpreventing use of a vehicle by an operator of the vehicle according tocertain embodiments of the present invention. As shown in FIG. 34, thesystem 2000 includes a control module (or system controller) 2016, abiometric authenticator (or fingerprint detector) 2012, a substancedetecting sensor (or detecting device or alcohol level detector) 2014,and/or an identity board 2018. The biometric authenticator 2012 iscoupled to the control module 2016 via a bus (e.g., via I2C Comm), andthe identity board 2018 is also coupled to the control module 2016 via abus (e.g., I2C Comm). The substance detecting sensor 2014 can be asubstance detecting sensor adapted to provide a substance level in auser (e.g., the third party, the person, the operator, etc.) to thecontrol module 2016 via a bus having a first laser control communicationline (Laser#1—Control), a second laser control communication line(Laser#2—Control), a detector communication line (Detector Out), a firsttemperature communication line (Temp #1), and a second temperaturecommunication line (Temp #2). Here, the control module 2016 is adaptedto communicate a driving restriction to the vehicle if the substancelevel in the operator is above a tolerance level or if the operator isnot authenticated by the authenticator 2012.

Also, in one embodiment of the present invention, the substance level isdetermined at an extremity of the operator, the operator is alsoauthenticated at the extremity, and the extremity is selected from thegroup composed of finger, thumb, toe, ear, palm, sole, foot, hand,and/or head.

In one embodiment, the control module 2016 is further adapted tocommunicate with the vehicle to permit the vehicle to start if theoperator has been authenticated by the authenticator 2012 and thesubstance level in the operator is not above the tolerance level.

In one embodiment, the substance detecting sensor 2014 is adapted todetect an alcohol level in the operator. Here, the substance detectingsensor 2014 may include a broadband detector (e.g., a single photodiodedetector) as described above. In addition, the substance detectingsensor may include a first diode laser configured to direct a light beamat a first specific wavelength toward the broadband detector and asecond diode laser configured to direct a light beam at a secondspecific wavelength toward the broadband detector. Here, the broadbanddetector may be coupled to a 16 bit analog/digital (A/D) interface ofthe control module 2016 via the detector communication line (DetectorOut). The first diode laser may be coupled to an input/output (I/O)interface of the control module 2016 via the first laser controlcommunication line (Laser#1—Control) and coupled to the 16 bit A/Dinterface of the control module 2016 via the first temperaturecommunication line (Temp #1), and the second diode laser may be coupledto the I/O interface of the control module 2016 via the second lasercontrol communication line (Laser#2—Control) and the 16 bit A/Dinterface of the control module 2016 via the second temperaturecommunication line (Temp #2).

In addition, FIG. 34 shows that the system controller 1010 is coupled toa user count switch, a program mode switch, a calibration mode switch, avalet mode switch and a display, and the identity board is coupled to avehicle bus and other vehicle system.

FIGS. 35, 36, 37, and 38 show flowcharts of process blocks of systemlogics for controlling a vehicle given to a third party, for in-vivomeasurement of a concentration of a substance in a tissue of a person,and/or for preventing use of a vehicle by an operator of the vehicleaccording to certain embodiments of the present invention. As shown inFIG. 35, the system logics has a main loop 3000 that can be operatingeither in a calibration mode 3100, a run mode 3300, or a valet mode3200. As shown in the main loop 3000 of FIG. 35, the system logicsdetermine if a calibration switch is turned on. As shown in FIGS. 35 and36, if the calibration switch is turned on, the system logics go intothe calibration mode 3100 by first displaying user count switch number(that may change) in block 3121. Referring to FIG. 36, in block 3122,the system logics read user count identification number. In block 3123,the system logics poll finger sensor identification. In block 3124, thesystem logics read alcohol detection sensor. The system logics thendetermine if a program switch has been pressed. If the program switchhas been pressed, the system logics store the fingerprint and alcoholdetection values at a persistent memory location (e.g., EEprom location)pointed to by the count reading in block 3125, and return to the mainloop 3000 in blocks 3126.

Referring back to FIG. 35, in the main loop 3000, if the calibrationswitch is not turned on, the system logics then determine if a valetswitch is turned on. As shown in FIGS. 35 and 37, if the valet switch isturned on, the system logics go into the valet mode 3200 by setting thevehicle's maximum speed to 10 miles per hour (MPH) in block 3141,enabling the vehicle to start in block 3142, and returning to the mainloop 3000.

Referring back to FIG. 35, in the main loop 3000, if the valet switch isnot turned on, the system logics then poll the fingerprint sensor inblock 3001 and determine if the finger is on the fingerprint sensor.Referring to FIGS. 35 and 38, if the finger of the user is on thefingerprint sensor, the system logics determine identification of theuser from the persistent memory in block 3332.

The system logics then determine if the user is recognized. If the useris not recognized, the system logics disable the vehicle in block 3333.If the user is recognized, the logics start alcohol detection. That is,the system logics turn on a first laser in block 3351, provide a waittime delay (e.g., from about 2 to about 3 ms) in block 3352. In block3353, the system logics then digitize the detector output sample, andaverage several samples (e.g., about 10 samples) to store this averagefirst laser value. In addition, as shown in FIG. 38, the system logicsturn on a second laser in block 3354, provide a wait time delay (e.g.,from about 2 to about 3 ms) in block 3355. In block 3356, the systemlogics then digitize the detector output sample, and average severalsamples (e.g., about 10 samples) to store this average second laservalue.

Then, as shown in FIG. 38, the system logic determine if the first laservalue or the second laser value is greater than a BAC threshold(s). Ifthe BAC threshold(s) is not exceeded, the system logics then return tothe main loop 3000. If the BAC threshold(s) is exceeded, the systemlogics then determined if the BAC limit is exceeded. If the BAC limit isexceeded, the system logics determine if the system override is on. Ifthe system override is not on, the system logics move to block 3333 todisable the vehicle. By contrast, if the system override is on or theBAC limit has not been exceeded, the system logics log this data inblock 3335, enable the vehicle to start in block 3336, and return to themain loop 3000.

Referring back to FIG. 35, in the main loop 3000, if the finger is noton the fingerprint sensor, the system logics then determine if a valuefrom a temperature sensor of the first laser is greater than a firstthreshold. If the value is greater than the first threshold, the systemlogics turn on a first laser TEC to cool the first laser. If the valueis not greater than the first threshold, the system logics thendetermine if a value from a temperature sensor of the second laser isgreater than a second threshold. If the value is greater than the secondthreshold, the system logics turn on a second laser TEC to cool thesecond laser. If the value is not greater than the second threshold,return back to the starting point of the main loop 3000.

In view of the foregoing, embodiments of the present inventions providea light source at a specific wavelength band for non-invasive and/orin-vivo testing of a concentration of a substance in a tissue of aperson; provide two or more specific wavelength bands for non-invasiveand/or in-vivo substance analysis; provide a base reading and a laterreading for comparison and/or determination of a concentration of asubstance in a tissue of a person; couple a biometric sensor with asubstance sensor at close proximate locations for concurrent and/orsubstantial simultaneous authentication and substance evaluation; and/orprovide a method and system for controlling a vehicle given to a thirdparty (e.g., a valet). In one embodiment of the present invention, anoptical substance detector includes a light source (e.g., a halogenlamp) and a fiber optic bundle attached to the halogen lamp toilluminate a test sample (e.g., an area of the test sample) with aconfigured wavelength filtering system. The desired wavelength bands arereflected back to a detector. Through an evaluation involving astatistical modeling analysis, the test sample's blood alcoholconcentration (BAC) is determined with respect to a legal limit tooperate an vehicle and, if the BAC is not within the legal limit, thevehicle is disabled.

It should be appreciated from the above that the various structures andfunctions described herein may be incorporated into a variety ofapparatuses (e.g., an imaging device, a monitoring device, etc.) andimplemented in a variety of ways. Different embodiments of the imagingand/or monitoring devices may include a variety of hardware and softwareprocessing components. In some embodiments, hardware components such asprocessors, controllers, state machines and/or logic may be used toimplement the described components or circuits. In some embodiments,code such as software or firmware executing on one or more processingdevices may be used to implement one or more of the described operationsor components.

While the present invention has been described in connection withcertain exemplary embodiments, it is to be understood that the inventionis not limited to the disclosed embodiments, but, on the contrary, isintended to cover various modifications and equivalent arrangementsincluded within the spirit and scope of the appended claims, andequivalents thereof.

1. A system for controlling a vehicle given to a third party, the systemcomprising: a system controller; a mode-indicating device coupled to thesystem controller; and a biometric authenticator coupled to the systemcontroller, the biometric authenticator adapted to detect at least onebiometric parameter at a first dermal location of an operator of thevehicle, a substance detecting device coupled to the system controllerand adapted to provide a substance level to the system controller, thesubstance detecting device adapted to detect a level of a substance inan operator of the vehicle at a second dermal location proximate to thefirst dermal location, wherein the system controller is adapted tocommunicate a driving restriction to the vehicle upon an activation ofthe mode-indicating device by an authorized driver, as determined by thebiometric authenticator, and until a deactivation of the mode-indicatingdevice by the authorized driver, wherein the system controller isadapted to restrict the activation of the mode-indicating device unlessthe authorized driver has been authenticated by the biometricauthenticator, wherein the system controller is adapted to restrict thedeactivation of the mode-indicating device unless the authorized driverhas been authenticated by the biometric authenticator and the substancelevel in the authorized driver, as determined by the substance detectingdevice, is not above a tolerance level, and wherein the drivingrestriction comprises a limit selected from the group consisting of alimit in number of starts, a limit in speed, a limit in acceleration, alimit in number of minutes, a limit in distance, a limit in gears, alimit in locations, and combinations thereof.
 2. The system of claim 1,wherein the system controller is further adapted to communicate with thevehicle to permit the vehicle to start if the substance level in thethird party is not above a tolerance level.
 3. The system of claim 2,wherein the system controller is further adapted to communicate anotherdriving restriction to the vehicle if the substance level in the thirdparty is above the tolerance level.
 4. The system of claim 3, whereinthe driving restriction comprises a command adapted to be sent via avehicle bus of the vehicle to limit a maximum speed of the vehicle, andwherein the another driving restriction comprises a command adapted tobe sent via the vehicle bus of the vehicle to block the vehicle fromstarting.
 5. The system of claim 1, wherein the substance detectingdevice comprises an optical detector.
 6. The system of claim 5, whereinthe substance detecting device further comprises a light sourceconfigured to direct a first light beam at a specific wavelength bandtoward the second dermal location, wherein the optical detector ispositioned to detect a resulting light beam from the interaction of thefirst light beam with the second dermal location.
 7. The system of claim6, wherein the specific wavelength band is within a range from about1300 nm to about 2400 nm.
 8. The system of claim 7, wherein the range isselected from the group consisting of a first range from about 1400 nmto about 1500 nm, a second range from about 1650 nm to about 1750 nm,and a third range from about 2200 nm to about 2400 nm.
 9. The system ofclaim 6, wherein the specific wavelength band is at about 1450 nm. 10.The system of claim 6, wherein the optical detector is selected from thegroup consisting of a single detector, a plurality of detectors and adetector array.
 11. The system of claim 10, wherein the optical detectoris an InGaAs detector.
 12. The system of claim 1, wherein the substancedetecting device comprises an optical detector, a first light beam at afirst specific wavelength band directed toward the second dermallocation, and a second light beam at a second specific wavelength banddirected toward the second dermal location and wherein the optical banddetector is positioned to detect a resulting light beam from theinteraction of the first light beam and the second light beam with thesecond dermal location.
 13. The system of claim 12, wherein the firstspecific wavelength band is at a wavelength where ethanol is lessabsorptive than water and the second specific wavelength band is at awavelength where ethanol is more absorptive than water.
 14. The systemof claim 12, wherein the optical detector is selected from the groupconsisting of a single detector, a plurality of detectors and a detectorarray.
 15. The system of claim 14, wherein the optical detector is anInGaAs detector.
 16. The system of claim 12, wherein the first specificwavelength band is within a range from about 1400 nm to about 1500 nmand the second specific wavelength band is within a range from about1650 nm to about 1750 nm.
 17. The system of claim 12, wherein the firstspecific wavelength band is within a range from about 1400 nm to about1500 nm and the second specific wavelength band is within a range fromabout 2200 nm to about 2400 nm.
 18. The system of claim 1, wherein thesubstance detecting device comprises an optical detector, a first lightbeam at a first specific wavelength band directed toward the seconddermal location broadband detector, a second light beam at a secondspecific wavelength band directed toward the second dermal location, anda third light beam at a third specific wavelength band directed towardthe second dermal location and wherein the optical detector ispositioned to detect a resulting light beam from the interaction of thefirst, second and third light beams with the second dermal location. 19.The system of claim 18, wherein the optical detector is selected fromthe group consisting of a single detector, a plurality of detectors anda detector array.
 20. The system of claim 18, wherein the first specificwavelength band is within a range from about 1400 nm to about 1500 nm,the second specific wavelength band is within a range from about 1650 nmto about 1750 nm, and the third specific wavelength band is within arange from about 2200 nm to about 2400 nm.
 21. The system of claim 20,wherein the first specific wavelength band is at about 1450 nm.
 22. Thesystem of claim 18, further comprising a light source configured toprovide the first, second, and third light beams.
 23. The system ofclaim 22 further comprising a filtering system disposed between thelight source and the optical detector and adapted to provide the first,second, and third light beams at the first, second, and third specificwavelength bands.
 24. The system of claim 1, wherein the substancedetecting device comprises an optical detector selected from the groupconsisting of a PbS detector, a PbSe detector, an InAs detector, anInGaAs detector, an InSb detector, and a HgCdTe detector and a lightsource adapted to direct a first light beam at a specific wavelength tothe second dermal location, and wherein the optical detector ispositioned to detect a resulting light beam from the interaction of thefirst light beam with the second dermal location.
 25. The system ofclaim 24, further comprising a wavelength filtering system disposedbetween the light source and the optical detector and adapted to providethe light beam at the specific wavelength band.
 26. The system of claim25, wherein the wavelength filtering system is disposed closer indistance to the optical detector than to the light source.
 27. Thesystem of claim 25, further comprising a platform coupled to both thelight source and the optical detector, wherein the platform isconfigured to contact a surface of the extremity of the operator and hasan index of refraction substantially equal to that of the surface ofextremity of the operator.
 28. The system of claim 1, wherein thesubstance detecting device comprises an optical detector, and a diodelaser configured to direct a first light beam at a specific wavelengthtoward the second dermal location, and wherein the optical detector ispositioned to detect a resulting light beam from the interaction of thefirst light beam with the second dermal location.
 29. The system ofclaim 28, wherein the specific wavelength is at about 1310 nm.
 30. Thesystem of claim 29, wherein the optical detector is a single photodiodedetector.
 31. The system of claim 1, wherein the substance detectingdevice comprises an optical detector, a first diode laser configured todirect a first light beam at a first specific wavelength toward thesecond dermal location, and a second diode laser configured to direct asecond light beam at a second specific wavelength toward the seconddermal location, and wherein the optical detector is positioned todetect a resulting light beam from the interaction of the first andsecond light beams with the second dermal location.
 32. The system ofclaim 31, wherein the first specific wavelength is at a wavelength whereethanol is less absorptive than water and the second specific wavelengthis at a wavelength where ethanol is more absorptive than water.
 33. Thesystem of claim 1, wherein the substance detecting device comprises anoptical detector, a first diode laser configured to direct a first lightbeam at a first specific wavelength toward the second dermal location, asecond diode laser configured to direct a second light beam at a secondspecific wavelength toward the second dermal location, and a third diodelaser configured to direct a third light beam at a third specificwavelength toward the second dermal location, and wherein the opticaldetector is positioned to detect a resulting light beam from theinteraction of the first, second and third light beams with the seconddermal location.
 34. The system of claim 1, wherein the drivingrestriction further comprises another limit selected from the groupconsisting of a limit in activatable accessories, a limit in openablecompartments, and combinations thereof.
 35. The system of claim 34,wherein the system controller is further adapted to send a message to acell phone if the limit has been exceeded to notify a designatedindividual remotely.
 36. The system of claim 35, wherein the systemcontroller is further adapted to create an alert if the limit has beenexceeded to notify the authorized driver when the authorized driverretakes control of the vehicle.
 37. The system of claim 1, wherein thethird party is a valet.
 38. The system of claim 1 wherein the substancedetecting device comprises a wide band light source and a spectroscopicevaluation device selected from the group consisting of a dispersivespectrometer, a filtering spectrometer, a single or multiple slitmonochrometer and a scanning slit monochrometer, to detect the level ofa substance in an operator of a vehicle.
 39. The system of claim 1wherein the substance detecting device comprises a single or multiplenarrow band light source, and single or multiple optical detectors.